EP2855789A1 - High-performance heat-insulating panel - Google Patents

Abstract

The invention proceeds from a high-performance heat-insulating panel for a composite heat-insulating system, having at least one outwardly directed surface (12a; 12b; 12d) which has an at least substantially organic high-performance insulting material (14a, 14c) with a coefficient of thermal conductivity smaller than 0.030 W/Km. It is proposed for the surface (12a; 12b; 12d) to have at least one recess (16a; 16b; 16c; 16d) provided for accommodating a fireproof material.

Description

 High-performance thermal insulation board

State of the art

The invention relates to a high-performance thermal insulation panel according to the preamble of claim 1.

From DE 10 2010 020 394 A1 is already a high-performance thermal insulation panel for a thermal insulation composite system, with at least one outward facing surface having an at least substantially organic high-performance insulating material with a thermal conductivity less than 0.030 W / Km known. Advantages of the invention

The invention is based on a high-performance thermal insulation panel for a

Heat insulation composite system, with at least one outward-facing surface having an at least substantially organic high-performance insulating material with a thermal conductivity of less than 0.030 W / Km. It is proposed that the surface has at least one recess which is provided for receiving a non-combustible material. As a result, a surface of the high-performance thermal insulation panel can be interrupted, which can be limited or prevented in a fire, a fire spread. In particular, this can limit or prevent the formation of pyrolysis gases, as a result of which a spread of fire can be effectively restricted. By an embodiment of the invention can thus be an organic

High-performance thermal insulation panel are provided, which in particular in a thermal composite system has an improved fire behavior, whereby applications are possible, such as for a high-rise, ie a building with a height over 22 m. A "recess" is to be understood in particular as meaning a material release in the high-performance insulating material, which in the case of a surface-mounted assembly of the Thermal insulation plate forms an outwardly facing groove. In particular, it should also be understood as meaning a material release which merely forms the groove in conjunction with at least one further high-performance thermal insulation panel into which the incombustible material can be introduced. An "at least substantially organic high-performance insulating material" is to be understood in particular as a high-performance insulating material which consists of at least 50 percent of an organic material Preferably, the insulating material consists of 90 percent organic material, more preferably 95 percent of the insulating material is an organic material Material, but it can also be completely made of one

consist of organic material. A "thermal conductivity" is to be understood in particular as a normalized value for a thermal conductivity of the high-performance insulating material, which results from EN 13165 and DIN 4108. A lower thermal conductivity

Thermal conductivity means a higher insulation effect.

It is further proposed that the recess runs parallel to a longitudinal side. As a result, a pyrolysis target height can be shortened particularly advantageously. In this context, a "longitudinal side" is to be understood as meaning, in particular, a side which limits the surface facing outward

Recess parallel to the longitudinal side, which has the largest dimension. In principle, however, the recess can also run obliquely to the longitudinal side. Preferably, an angle between the longitudinal side and the recess is less than 45 degrees.

Preferably, the recess has a depth that is less than a thickness of the high-performance insulation material. This can be avoided

Forming thermal bridges, whereby a good thermal conductivity can be achieved over the entire surface. In particular, it is proposed that the depth of the recess is at least 30 percent of the thickness of the high-performance insulating material, whereby one for a good

Fire protection effect required depth can be realized with low heat loss. Preferably, the depth of the recess is at least 50 percent of the thickness, and more preferably at least 80 percent of the thickness. At the same time, a maximum depth of the recess of 120 mm can be considered sufficient, wherein to maintain an insulating effect preferably a residual thickness in the region of the recess should be present. Depending on the thickness of the insulation board This results in different values, which are advantageous for the depth. Advantageously, the depth is between 40 mm and 120 mm, in particular between 60 mm and 100 mm, and particularly advantageously about 80 mm, whereas the thickness of the insulating board may for example be in the range between 100 mm and 120 mm. The thickness of the insulating board can basically be much smaller or significantly larger.

The high-performance thermal insulation panel preferably has a residual insulation thickness of at least 20 mm in the region of the recess. This allows a thermal bridge-free insulation can be achieved. At the same time, a stability of the high-performance insulating panel can largely be maintained, which in particular makes simple assembly possible, since high-performance thermal insulation panels can be handled equally with and without a recess. The term "residual insulation thickness" corresponds to the thickness of the thermal insulation panel minus the depth of the recess, and it is particularly advantageous if the depth of the recess is at least This makes it possible to achieve a high level of protection against the spread of fire, since in particular it is possible to avoid damaging the high-performance insulation material in the area of the recess, while at the same time maintaining a high residual insulation thickness, in particular if the thickness of the recess is high

Hochleitungswärmedämmplatte, whereby a good thermal insulation can be achieved.

Particularly advantageously, the high-performance insulating material is designed as a PUR and / or PIR foam. This allows a particularly low thermal conductivity can be achieved, whereby a good insulation can be provided. In particular, by this heat conductivities less than or equal to 0.025 W / Km for the

 High-performance thermal insulation panel can be achieved. A "PUR foam" is to be understood as meaning rigid polyurethane foam

Polyisocyanurate hard foam can be understood.

Furthermore, a high-performance thermal insulation panel for a thermal insulation composite system, which is an at least substantially high-performance organic insulating material with a thermal conductivity of less than 0.030 W / Km and at least one outwardly facing Surface, proposed, wherein the high-performance thermal insulation panel has at least one fire protection strip, which is integrated in the high-performance insulating material. As a result, a fire spread within the

High-performance thermal insulation board, in particular a fire propagation along the surface of the high-performance heat insulation, be effectively avoided, which means the high-performance thermal insulation board, a thermal insulation composite system can be created, the fire protection properties meet higher requirements than the fire protection properties of the high performance thermal insulation expected. By such a configuration can thus easily a barrier against

Fire propagation can be created, which can effectively prevent the spread of fire, especially when the high-performance thermal insulation panel is covered with a cleaning system. A "fire protection strip" is to be understood in particular a strip made of a non-combustible material according to building material class A1 or A2 in accordance with DIN 4102. Basically, however, other materials are also conceivable which is at least a factor of 2, preferably at least a factor of 5 and more preferably at least a factor of 10 greater than a thickness of the fire protection strip and a strength of the fire protection strip. By "integrated" is meant in particular that the fire protection strip is surrounded on at least two sides, but preferably on at least three sides, by the high-performance insulating material

surrounding sides of the high performance insulating material.

The high-performance thermal insulation panel preferably has at least one

Recess in which the at least one fire protection strip is inserted. This is a particularly simple and inexpensive production of

High-performance thermal insulation panel with integrated fire protection strip possible.

Preferably, the fire protection strip is made of a solid, inserted into the recess material. This makes the fire protection strip easy to install. As the material are different, non-combustible materials conceivable, in particular non-combustible, inorganic materials. For example, the fire protection strip can be formed from an inorganic insulating material. But there are others too Materials, in particular composite materials or mineral materials are used. In addition, it is also conceivable that the fire protection strip is not in the

Insert recess, but the fire strip with the

To foam over high-performance insulating material. Particularly advantageously, the fire protection strip is aligned at least substantially perpendicular to the surface facing out Shen. This can be an effective one

Fire protection can be achieved without damper property are significantly changed. By "at least substantially perpendicularly oriented" is to be understood in this context in particular that the thickness of the fire protection strip at least by a factor of 2, preferably at least a factor of 5 and more preferably at least by a factor 10 is greater than the strength of the fire protection strip a "thickness" of the fire protection strip is intended in particular a dimension of

Fire protection strip in a direction perpendicular to the outward-facing surface to be understood. A "strength" of the fire protection strip is to be understood, in particular, a dimension of the fire protection strip parallel to the surface facing outward Shen.

Preferably, the firestop has a thickness of at most 10 mm.

As a result, fire propagation along the outward-facing surface beyond the fire protection strip can be effectively avoided. At the same time the fire protection strip can be made of a material, the good

 Fire protection properties, since a thickness of at most 10 mm can be covered with a cleaning system, even if the cleaning system and the

Fire protection strip no material connection enter. Thus, a good fire protection effect with homogeneous surface of the plaster system can be easily achieved. Preferably, the fire protection strip has a thickness of at most 5 mm.

Most preferably, the thickness is equal to or less than 3 mm.

It is further proposed that the fire protection strip has a thickness which is at most equal to a depth of the recess. This can be a supernatant of

Fire protection strip are avoided beyond the surface, whereby a good connection to the cleaning system can be provided. Preferably, the fire protection strip has a thickness of at least 40 mm. As a result, it can be at least largely avoided that a fire spreads by infiltrating the fire protection strip.

It is also proposed that the fire protection strip extends transversely across the entire outward-facing surface, whereby an arrangement of several high-performance thermal insulation panels side by side

Fire protection bolt can be created. Taking "across the entire

In this case, it should be understood in particular that the fire protection strip has a longitudinal extension which corresponds to a dimension of the

High-performance thermal insulation board in the longitudinal direction corresponds. At the same time, however, the strength of the fire protection strip is much smaller than a dimension of the

High performance insulation board in transverse direction.

Preferably, the fire protection strip is formed of a solid material.

In principle, it is also conceivable that the fire protection strip is formed from a hardened after being introduced into the recess material. As a result, the recess can be filled particularly well. For example, the recess can form an undercut, whereby a particularly high strength in the connection between the fire protection strip and the high-performance insulating material can be achieved. In addition, a thermal insulation composite system for a high-rise building or a building with special fire protection requirements with at least one invention

High-performance thermal insulation panel proposed. This can be a

Thermal insulation composite system are provided with a low thermal conductivity, which meets increased fire safety requirements and thus also for buildings with special fire safety requirements, in particular skyscrapers, can be approved.

It is also proposed that the high performance thermal insulation board a

Having fire protection strip and the composite thermal insulation system comprises a cleaning system that is coupled to the fire protection strip of the high-performance thermal insulation board. As a result, a fire behavior of the thermal insulation composite system can be further improved. In addition, it is proposed that the thermal insulation composite system has at least one lintel, to which at least one fire protection strip has a distance of at least 300 mm and / or at most 700 mm. As a result, an area between the lintel and the fire protection strip can be formed as a victim area, in which damage is accepted in the event of a fire in order to prevent the spread of fire beyond the fire protection strip. Preferably, therefore, the fire protection strip, which has a distance of at least 300 mm to the fall, the closest to the fall fire protection strip. In this context, a "fall" is to be understood as meaning in particular that part of the thermal insulation composite system which is arranged directly above an opening, such as a window opening or a door opening, for example.The fall is preferably formed by a horizontal termination of the thermal insulation composite system above the opening In addition, it is proposed that the thermal insulation composite system has at least two fire protection strips arranged parallel to one another, which have a spacing of at least 300 mm and / or at most 1000 mm in the event of damage to the high-performance thermal insulation material, a further spread above the fire protection strip closest to the fall is prevented.

At the same time, an area which is damaged in the event of a fire can advantageously be kept small.

drawings

Further advantages emerge from the following description of the drawing. In the drawings, different embodiments of the invention are shown. The drawings, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

Show it: Fig. 1 is a detail view of a high-performance thermal insulation board of a

 Thermal insulation composite system for a skyscraper or other building with special fire protection requirements,

Fig. 2 is a thermal insulation composite system for a high-rise building with different

 High performance thermal insulation sheets,

 Fig. 3 is a detail view of a high-performance thermal insulation board with

 Fire protection strips,

 4 shows a detail view of a high-performance thermal insulation panel with a

 Fire protection strip, which is arranged in an edge region, and

Fig. 5 is a detail view of a high performance thermal insulation board with a

 Fire protection bar.

Description of the embodiments

In Figures 1 and 2 is a composite thermal insulation system for a high-rise building with a building height over 22 meters or other building application with increased

Fire safety requirements, such as a meeting room or a public building represented. The thermal insulation composite system has a plurality of high-performance thermal insulation panels 10a, 11a, which are to be insulated

Wall are arranged. The illustrated thermal insulation composite system is

intended in particular for vertical walls. The high-performance thermal insulation panels 10a, 11a are made of a non-fusible material

High-performance insulating material 14a, 15a with a thermal conductivity less than 0.030 W / Km (see Figure 1). In the illustrated embodiment, the high-performance insulating material 14a, 15a, of which the high-performance thermal insulation panels 10a, 11a are, are formed as PUR and / or PIR hard foam. The high-performance thermal insulation panels 10a, 11a have a size of approximately 1000 × 500 mm. But they can also be made in other sizes. Typically, the high-performance thermal insulation panels 10a, 11a are mounted transversely, ie longitudinal sides 18a, 19a of the high-performance thermal insulation panels 10a, 11a extend parallel to a horizontal. The high-performance thermal insulation panels 10a, 11a preferably each have a thickness 22a of at least 60 mm. In the illustrated embodiment, they have a thickness 22a of about 100 mm. In the case of the high-performance thermal insulation panels 10a, at least one recess 16a, which can be filled with an incombustible material, is introduced into the high-performance insulation material 14a of the corresponding high-performance thermal insulation panel 10a. The recesses 16a of the high-performance thermal insulation panels 10a each extend parallel to the longitudinal side 18a of the corresponding high-performance thermal insulation panel 10a. The longitudinal side 18a is the longest side of the

 High performance thermal insulation board 10a. In principle, however, the recesses 16a can also run in a different direction, in particular also parallel to one of the shorter sides. The recess 16 a is inserted into a surface 12 a of the high-performance thermal insulation panel 10 a, which is turned outward in the assembled state. A depth 20a of the recess 16a is less than the thickness 22a of the high-performance insulating material 14a. The recess 16a forms into the high-performance insulating material 14a

introduced groove. The recess 16a points in the illustrated

Embodiment a depth 20a of about 80 mm. The high-performance insulating material 14a of the high-performance thermal insulation board 10a has a thickness 22a of at least 100 mm. In the area of the recesses 16 a, the

 High-performance thermal insulation board 10a so that a residual thickness 17a of about 20 mm. The high-performance thermal insulation panels 10a are thus free of thermal bridges. In principle, it is advantageous if the depth 20a of the recess 16a is at least 30 percent of the thickness 22a of the high-performance insulating material 14a. In the region of the recess 16a, the residual insulating thickness 17a is preferably at least 20 mm, wherein in particular a residual insulating thickness 17a of 20 mm to 40 mm is advantageous.

The high-performance thermal insulation panel 10a, which has the recess 16a, further has a fire protection strip 24a, which is inserted into the recesses 16a. The fire protection strip 24a has a longitudinal extension which is the same size as a longitudinal extent of the high-performance thermal insulation panel 10a. The fire protection strip 24a thus extends over the entire outward-facing surface 12a of the

High performance thermal insulation board 10a. In addition, the fire protection strip 24a has a thickness 26a which is the same size as the depth 20a of the recess 16a. The fire protection strip 24a thus closes flush with the surface 12a of the high-performance thermal insulation board The fire protection strip 24a is made of an inorganic, non-combustible material. As a material for the fire protection strip 24a, for example, a silicate is used, which is bound mineral. Alternatively, a magnesium-based mineral-bound material or other mineral-bonded material may also be used. The fire protection strip 24a has a thickness 27a of the highest 10 mm. The thickness 27a of the fire protection strip 24a is in the illustrated

Embodiment about 3 mm. The fire protection strip is used in particular as

Pyrolysegasbarriere. A thermal fire protection effect by the fire protection strip 24a, i. a separation into two mutually thermally separated areas, is

negligible.

Alternatively, as the material for the fire protection strip 24a and an inorganic

Insulating material can be used. As a material for the fire protection strips 24a, for example, rock wool can be used. The surfaces 12a of the

High-performance thermal insulation panels 10a thus have a hybrid structure, which consists partly of at least substantially organic insulating material and partly of at least substantially inorganic insulating material. A large part of the surface 12a is characterized by the at least substantially organic

Insulating material formed.

In addition, in a thermal insulation composite system, the surface 12a of

High performance thermal insulation panels 10a completely or partially coated with a fire protection material. The fire protection material is preferably in the form of a plaster system 28a, which is applied to the high-performance thermal insulation panels 10a (see Figures 2 and 4). The cleaning system 28a enters into a material connection with the corresponding fire protection strip 24a, whereby the cleaning system 28a is coupled to the fire protection strips 24a directly or via the fire protection material designed as an additional layer. The cleaning system 28a and the fire protection strips 24a thereby form a horizontal and vertical lining of the high-performance insulating material 14a, which divides the outwardly facing surface 12a into segments and the one

Prevents the spread of fire from one segment over one of the fire protection strips 24a into an overlying segment. The cleaning system 28a is preferably constructed on a mineral basis. But it is also conceivable that the fire protection material forms an additional layer which is applied to the high-performance thermal insulation panel 10a and then the plaster system 28a can be applied. The fire protection material brings no functional for the overlying plaster system 28a

Impairments with it. Rather, the cleaning system 28a goes with the

Fire protection material a cohesive connection.

When attached to a skyscraper or other building with special fire protection conditions, the high performance thermal insulation panels 10a

preferably mounted so that the recesses 16a extend in the horizontal direction. High-level thermal insulation panels 10a of the same type are always arranged in one plane. The fire protection strips 24a of the individual high-performance thermal insulation panels 10a thus directly adjoin one another, as a result of which the fire protection strips 24a form a continuous ring in the horizontal direction, which in particular can also extend around a complete circumference of a building. The fire protection strip 24a is au ßermittig introduced into the high-performance thermal insulation panel 10a. Distances which the fire protection strip 24a have to the respective parallel longitudinal sides 18a of the high-performance thermal insulation panels 10a are

different sized. As a result, the high-performance thermal insulation panels 10a arranged in one plane must necessarily be arranged with the same orientation so that the fire protection strips 24a of adjacent high-performance thermal insulation panels 10a directly adjoin one another.

Furthermore, the composite thermal insulation system advantageously has a plurality of superposed high-performance thermal insulation panels 10a with fire protection strips 24a. By orienting the high performance thermal insulation panels 10a differently, the fire barriers 24a may be spaced apart. In the illustrated embodiment, a composite thermal insulation system with several high-performance thermal insulation panels 10a, 1 1 a is shown, of which the lowermost forms a camber 29a as a conclusion above an opening. The fire protection strip 24a of the lowermost high-performance thermal insulation panel 10a has a distance to the lintel 29a at a distance of between 300 mm and 700 mm. The

Fire protection strip 24a of the uppermost high-performance thermal insulation panel 10a preferably has a maximum distance from the fall 29a of 2000 mm. The Fire protection strip 24a of the middle high-performance thermal insulation panel 10a is arranged off-center between the fire protection strip 24a of the uppermost high-performance thermal insulation board 10a and the fire protection strip 24a of the lowermost high-performance thermal insulation board 10a. The high performance thermal insulation panels 10a, which are the one above the other

arranged fire protection strips have 24a are each formed identically. The different distances are due to the different orientations of the

High performance thermal insulation panels 10a and / or by arranging

High performance thermal insulation panels 1 1 a without fire protection strips between

High-performance thermal insulation panels 10a realized with fire protection strips 24a. In

Depending on structural conditions, the thermal insulation composite system can also be realized with a different number of fire protection strips 24a and / or deviating distances of the fire protection strips 24a relative to each other and / or with respect to the lintel 29a.

Preferably, the thickness 27a of the fire protection strip 24a is less than 10 mm in order to ensure a uniform coverage with a cleaning system 28a.

In principle, however, the thickness 27a of the fire protection strip 24a can also be greater than 10 mm, in particular if the fire protection strip 24a is provided on its side facing the exterior with an adhesion promoter for the plaster system 28a. As adhesion promoter, the fire protection strip 24a can be provided, for example, with a layer of the high-performance insulation material 14a. For this purpose, the fire protection strip 24a may be formed with a thickness 26a which is slightly smaller than the depth 20a of the recess 16a. This allows the fire protection strip 24a with the layer of

Hochleistungsdämmmaterials 14a are covered. The layer which the

Fire protection strip 24a covered, is preferably only a few millimeters thick. In a preferred production, the high-performance thermal insulation panels 10a, 11a are first produced without the recesses 16a for the fire protection strips 24a, for example by frothing a block of the high-performance insulation material 14a and cutting it after it has hardened. The recess 16a is then introduced into the high-performance thermal insulation panels 10a, for example by milling.

Subsequently, the fire protection strips 24a are inserted into the recesses 16a. The fire protection strips 24a are preferably at its lower edge with a Adhesive provided, which the fire protection strips 24 a and the

High performance insulation material 14a firmly connects.

If the fire bars 24a are to be covered with a layer of the high performance insulating material 14a or other material, i. the thickness 26a of

Fire protection strips 24a is less than the depth 20a of the recess 16a, is

then the part of the recess 16 a, which after the introduction of the

Fire protection strips 24a remains, with a strip of

High performance insulation material 14a filled. Preferably, the strip is formed of hardened insulating material and is glued into the recess 16a. However, it is also conceivable in principle to foam out the remaining part of the recess 16a and thereby to form the strip. Alternative to this

However, manufacturing processes are also other manufacturing and / or

Mounting method conceivable, such as a production by

Foaming of the fire protection strips 24a. Three further embodiments of the invention are shown in FIGS. The following descriptions are essentially limited to the differences between the embodiments, with respect to constant components,

Features and functions on the description of the other embodiments, in particular the figures 1 and 2, can be referenced. To distinguish the embodiments, the letter a in the reference numerals of

 Embodiment in Figures 1 and 2 by the letters b to d in the

Reference numerals of the embodiments of Figures 3 to 5 replaced. With regard to identically named components, in particular with regard to components with the same reference numerals, reference may in principle also be made to the drawings and / or the description of the other exemplary embodiments, in particular FIGS. 1 and 2.

FIG. 3 shows an embodiment of a high-performance thermal insulation panel 10b with two recesses 16b and two fire protection strips 24b, each in one of the

Recesses 16b are inserted. The fire protection strips 24b each have a longitudinal extension which is the same size as a longitudinal extent of the

High performance thermal insulation panel 10b. In addition, the fire protection strips 24b each have a thickness 26b which is the same size as a depth 20b of the recess 16b. The Fire protection strips 24b thus terminate flush with the surface 12b of the high-performance thermal insulation board 10b.

FIG. 4 shows, as a further embodiment, a high-performance thermal insulation panel 10c, in which a fire protection strip 24c in an edge region of the

High performance thermal insulation board 10c arranged. Through a recess 16c, the high-performance insulating material 14c is stepped in the edge region. A groove into which the fire protection strip 24c is inserted is limited only in its depth 20c and on one side by the high-performance thermal insulation board 10c. On a second side, the groove through the not shown adjacent

High performance thermal insulation board limited. The recess 16c of

 High-performance thermal insulation panel 10c thus forms a groove only in combination with the further high-performance thermal insulation panel, with basically any desired

High performance thermal insulation panels can adjoin the high performance thermal insulation panel 10c. FIG. 5 shows a fourth embodiment of a high-performance thermal insulation panel 10d in which a recess 16d is filled with an incombustible material which has been introduced into the recess 16d in liquid or pasty form. After the material has hardened in the recess 16d, it forms a fire protection strip 24d, which likewise restrains or prevents a fire propagation on a surface 12d of the high-performance thermal insulation panel 10d.

The illustrated embodiments represent different embodiments that can be used individually or in combination. In a thermal insulation composite system according to the invention are in particular

High performance thermal insulation panels with fire protection strips and

High-performance thermal insulation panels without fire protection strips combined. The high-performance thermal insulation panels are preferably arranged on a wall at regular intervals. In particular, an arrangement above openings, such as window opening or door opening, advantageous. reference numeral

 10 high-performance thermal insulation board

1 1 high-performance thermal insulation board

12 surface

 14 high-performance insulation material

15 high-performance insulation material

16 recess

 17 Residual thickness

 18 long side

 19 long side

 20 depth

22 thickness

 24 fire protection strip

 26 thickness

 27 strength

 28 cleaning system

 29 fall

Claims

claims

1 . High-performance thermal insulation panel for a thermal insulation composite system, with

 at least one outwardly facing surface (12a; 12b; 12d) comprising an at least substantially high performance organic insulating material (14a, 14c) having a thermal conductivity less than 0.030 W / Km,

 characterized in that

 the surface (12a; 12b; 12d) has at least one recess (16a; 16b; 16c; 16d) provided for receiving a non-combustible material.

2. High-performance thermal insulation panel according to claim 1,

 characterized in that

 the recess (16a; 16b; 16c; 16d) runs parallel to a longitudinal side (18a).

3. High-performance thermal insulation panel according to one of the preceding claims, characterized by

 a residual insulation thickness (17a) of at least 20 mm in the region of the recess (16a; 16b; 16c; 16d).

4. High-performance thermal insulation panel according to claim 3 or 4,

 characterized in that

 the recess (16a; 16b; 16c; 16d) has a depth (20a; 20b; 20c) of at least 60 mm.

5. High-performance thermal insulation panel according to one of the preceding claims, characterized in that

the high-performance insulation material (14a, 14c) is formed of a PUR and / or PIR foam.

6. High-performance thermal insulation panel for a thermal insulation composite system, which has an at least substantially high-performance organic insulating material (14a, 14c) with a thermal conductivity of less than 0.030 W / Km and at least one outwardly facing surface (12a, 12b, 12d),

 marked by

 at least one fire protection strip (24a; 24b; 24c; 24d) inserted in the

 High performance insulation material (14a, 14c) is integrated.

7. high-performance thermal insulation panel according to claim 6,

 characterized in that

 the fire protection strip (24a; 24b; 24c; 24d) is aligned at least substantially perpendicular to the outwardly facing surface (12a; 12b; 12d).

8. high-performance thermal insulation panel according to claim 6 or 7,

 characterized in that

 the fire protection strip (24a, 24b, 24c, 24d) has a thickness (27a) of at most 10 mm.

9. high-performance thermal insulation board at least according to claim 6,

 characterized in that

 the fire protection strip (24a; 24b; 24c; 24d) has a thickness (26a; 26b) of at least 40 mm.

10. High-performance thermal insulation panel at least according to claim 6,

 characterized in that

 the fire protection strip (24a; 24b; 24c; 24d) extends over the entire outward-facing surface (12a; 12b; 12d).

1 1. High-performance thermal insulation panel at least according to claim 6,

 characterized in that

the fire protection strip (24a; 24b; 24c; 24d) is made of a solid material.

12. Thermal insulation composite system for a high-rise building with at least one

 High-performance thermal insulation panel (10a; 10b; 10c; 10d) at least according to claim 6.

13. thermal insulation composite system according to claim 12,

 marked by

 a cleaning system (28a) coupled to a firewall (24a; 24b; 24c; 24d) of the high performance thermal insulation panel (10a; 10b; 10c; 10d).

14. thermal insulation composite system according to claim 12 or 13,

 marked by

 at least one lintel (29a), to which at least one fire protection strip (24a) has a distance of at least 300 mm and / or at most 700 mm.

15. thermal insulation composite system at least according to claim 12,

 marked by

 at least two mutually parallel fire protection strips (24a, 24b), which have a distance of at least 300 mm and / or at most 1000 mm.