DE102012010265A1 - High-performance thermal insulation board - Google Patents

Abstract

The invention is based on a high-performance thermal insulation panel for a thermal insulation composite system, with at least one outwardly facing surface (12 ', 12' ', 12' '') comprising an at least substantially organic high-performance insulating material (14 ', 14' ', 14' '). ) having a thermal conductivity of less than 0.030 W / Km. It is proposed that the surface (12 ', 12' ', 12' '') at least one recess (16 ', 16' ', 16' ''), which is provided for receiving a non-combustible material.

Description

State of the art

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

From the DE 10 2010 020 394 A1 is already a high performance thermal insulation panel for a thermal insulation composite system, with at least one outwardly facing surface having an at least substantially high performance organic 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 thermal insulation composite system, with at least one outwardly facing surface comprising an at least substantially high-performance organic 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 means of an embodiment according to the invention, it is thus possible to provide an organic high-performance thermal insulation panel which, in particular in a heat-bonding system, has improved fire behavior, as a result of which applications are possible, for example for a high-rise building, i. H. 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 forms an outwardly facing groove in the case of a surface mounting of the thermal insulation panel. 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 organic material. Preferably, the insulating material consists of 90 percent of an organic material. Particularly preferably, the insulating material consists of 95 percent of an organic material. In principle, however, it can also consist entirely of an organic material.

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" should be understood to mean, in particular, a side which limits the surface facing outwards. Preferably, the recess is 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 that form 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 most 50 percent of the thickness of the high-performance insulating material, whereby heat loss can be kept to a minimum.

It is also proposed that the high-performance thermal insulation panel has at least one fire protection strip which is inserted into the at least one recess. As a result, a barrier against the spread of fire can be easily created, which can effectively prevent the spread of fire, in particular, when the high-performance thermal insulation panel is covered with a plaster system.

The fire protection strip is preferably made of a solid material inserted into the recess. This makes the fire protection strip easy to install. As the material are different, non-combustible materials conceivable, in particular non-combustible, inorganic materials. Preferably, the fire protection strip is made of an inorganic insulating material. However, it is also possible to use other materials, in particular composite materials or mineral materials.

It is further proposed that the fire protection strip has a thickness which is at most equal to a depth of the recess. As a result, a projection of the fire protection strip over the surface can be avoided, whereby a good connection to the cleaning system can be provided.

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.

Particularly advantageously, the high-performance insulating material is formed from a PUR and / or PIR foam. As a result, a particularly low thermal conductivity can be achieved, whereby good insulation can be provided. In particular, heat conductivities of less than or equal to 0.025 W / Km can be achieved for the high-performance thermal insulation panel. A "polyurethane foam" should be understood to mean rigid polyurethane foam. A "PIR foam" should be understood as meaning a rigid polyisocyanurate foam.

In addition, a thermal insulation composite system for a high-rise building with at least one high-performance thermal insulation panel according to the invention is proposed. As a result, a thermal insulation composite system with a low thermal conductivity can be provided, which meets increased fire requirements and thus can also be approved for buildings with special fire protection requirements.

It is further proposed that the high-performance thermal insulation panel has a fire protection strip and the composite thermal insulation system comprises a cleaning system which is coupled to the fire protection strip of the high-performance thermal insulation panel. As a result, a fire behavior of the thermal insulation composite system can be further improved.

drawings

Further advantages emerge from the following description of the drawing. In the drawings, an embodiment of the invention is 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:

1 a thermal insulation composite system for a high-rise building with different high-performance thermal insulation panels,

2 a detailed view of a high-performance thermal insulation panel with two fire protection strips,

3 a detailed view of a high-performance thermal insulation panel with a fire protection strip, which is arranged in an edge region, and

4 a detailed view of a high-performance thermal insulation panel with a fire protection strip.

Description of the embodiment

In the 1 to 4 is a composite thermal insulation system for a skyscraper with a building height over 22 meters or another building application with increased fire protection requirements, such as a meeting room or a public building represented. The thermal insulation composite system has a variety of high performance thermal insulation panels 10 ' . 10 '' . 10 ''' on, which are arranged on a wall to be insulated. The illustrated thermal insulation composite system is provided in particular for vertical walls.

The high performance thermal insulation panels 10 ' . 10 '' . 10 ''' are made from a non-meltable high performance insulation material 14 ' . 14 '' . 14 ''' with a thermal conductivity less than 0.030 W / Km. In the illustrated embodiment, the high performance insulating material 14 ' . 14 '' . 14 ''' from which the high-performance thermal insulation panels 10 ' . 10 '' . 10 ''' are formed as PUR and / or PIR hard foam. The high performance thermal insulation panels 10 ' . 10 '' . 10 ''' have a size of about 1000 × 500 mm. But they can also be made in other sizes. Typically, the high performance thermal insulation panels 10 ' . 10 '' . 10 '' transversely mounted, ie a longitudinal side 18 ' . 18 '' . 18 ' the high performance thermal insulation panels 10 ' . 10 '' . 10 ''' runs parallel to a horizontal. The high performance thermal insulation panels 10 ' . 10 '' . 10 ''' have a thickness of at least 60 mm. In the illustrated embodiment, they have a thickness of about 100 mm.

For the high-performance thermal insulation panels 10 ' . 10 '' . 10 ''' is in the high performance insulation material 14 ' . 14 '' . 14 ''' the corresponding high-performance thermal insulation board 10 ' . 10 '' . 10 ''' in each case at least one recess 16 ' . 16 '' . 16 ''' introduced, which can be filled with a non-combustible material. The recesses 16 ' . 16 '' . 16 ''' the high performance thermal insulation panels 10 ' . 10 '' . 10 ''' each run parallel to the long side 18 ' . 18 '' . 18 ' the corresponding high-performance thermal insulation board 10 ' . 10 '' . 10 ''' , The long side 18 ' . 18 '' . 18 ' is the longest side of the high-performance thermal insulation panel 10 ' . 10 '' . 10 ''' , Basically, the recesses can 16 ' . 16 '' . 16 ''' but also in a different direction, especially parallel to one of the shorter sides.

The recess 16 ' . 16 '' . 16 ''' is in a surface 12 ' . 12 '' . 12 ''' the high performance thermal insulation panel 10 ' . 10 '' . 10 ''' introduced, which is turned in the mounted state to the outside. A depth 20 ' . 20 '' . 20 ''' the recess 16 ' . 16 '' . 16 '' is less than a thickness 22 ' . 22 '' . 22 ''' of high performance insulation material 14 ' . 14 '' . 14 '' , The recess 16 ' . 16 '' . 16 ''' forms one in the high performance insulation material 14 ' . 14 '' . 14 ''' introduced groove. The recess 16 ' . 16 '' . 16 ''' has a depth in the illustrated embodiment 20 ' . 20 '' . 20 ''' from about 20-30 mm up. The high performance insulation material 14 ' . 14 '' . 14 ''' the high performance thermal insulation panel 10 ' . 10 '' . 10 ''' has a thickness 22 ' . 22 '' . 22 ''' of 100 mm. The high performance thermal insulation panels 10 ' . 10 '' . 10 ''' are thus free of thermal bridges. Basically, it is beneficial if the depth 20 ' . 20 '' . 20 ''' the recess 16 ' . 16 '' . 16 ''' no more than 30 percent of the thickness 22 ' . 22 '' . 22 ''' of high performance insulation material 14 ' . 14 '' . 14 ''' is.

As a possible embodiment, the high-performance thermal insulation panel 10 ' two recesses 16 ' as well as two fire protection strips 24 ' on, each in one of the recesses 16 ' are inserted (see. 2 ). The fire protection strips 24 ' each have a longitudinal extent that is the same size as a longitudinal extent of the high-performance thermal insulation panel 10 ' , In addition, the fire strips 24 ' one thickness each 26 ' on, which is the same size as a depth 20 ' the recess 16 ' , The fire protection strips 24 ' thus close flush with the surface 12 ' the high performance thermal insulation panel 10 ' from.

As a further embodiment, the high performance thermal insulation panel 10 '' the fire protection strip 24 '' in an edge region of the high-performance thermal insulation board 10 '' arranged (cf. 3 ). Through the recess 16 '' is the high performance insulation material 14 '' formed stepped in the edge region. The groove in which the fire strip 24 '' is introduced, only in depth 20 '' and on one side through the high performance thermal insulation board 10 '' limited. On a second side, the groove is through the adjacent high-performance thermal insulation board 10 ' limited. The recess 16 '' the high performance thermal insulation panel 10 '' thus forms only in combination with the other high-performance thermal insulation board 10 ' a groove, with basically any high-performance thermal insulation panels to the high-performance thermal insulation board 10 '' can border.

As a third embodiment, in the high-performance thermal insulation board 10 ''' the recess 16 ''' filled with an incombustible material in liquid or pasty form in the recess 16 ''' was introduced (see. 4 ). After the material in the recess 16 ''' is cured, it forms the fire protection strip 24 ' which also causes a fire spread on the surface 12 ''' the high performance thermal insulation panel 10 ''' Contains or prevents.

The fire protection strips 24 . 24 '' . 24 ' are made of an organic, non-combustible material. The material is designed as an organic insulating material. As material for the fire protection strips 24 ' . 24 '' . 24 ' For example, rock wool can be used. The surfaces 12 ' . 12 '' . 12 ''' the high performance thermal insulation panels 10 ' . 10 '' . 10 ''' thus have a hybrid structure, which consists partly of at least substantially organic insulating material and partly of at least substantially inorganic insulating material. Much of the surface 12 ' . 12 '' . 12 ''' is formed by the at least substantially organic insulating material.

In addition, the surface can be 12 ' . 12 '' . 12 ''' the high performance thermal insulation panels 10 ' . 10 '' . 10 ''' wholly or partially coated with a fire protection material. The fire protection material can be in the form of a plaster system 28 on the high-performance thermal insulation panels 10 ' . 10 '' . 10 ''' to be upset (cf. 2 and 4 ). But it is also conceivable that the fire protection material forms an additional layer on the high-performance thermal insulation board 10 ' . 10 '' . 10 ''' is applied and can then be applied to a cleaning system. The fire protection material brings with it no functional impairments for the cleaning system structure arranged above it. Rather, the cleaning system goes 28 with the appropriate fire protection strip 24 ' . 24 '' . 24 '' a cohesive connection, whereby the cleaning system 28 with the fire bars 24 ' . 24 '' . 24 ' is coupled. The cleaning system 28 and the fire bars 24 ' . 24 '' . 24 ' thereby forming a horizontal and vertical cladding of the high performance insulation material 14 ' . 14 '' . 14 ''' out, that the outward facing surface 12 ' . 12 '' . 12 ''' divided into segments and that a fire spread from a segment on one of the fire protection strips 24 ' . 24 '' . 24 ' prevented in a segment arranged above it.

Attached to the skyscraper are the high performance thermal insulation panels 10 ' . 10 '' . 10 ''' mounted so that the recesses 16 ' . 16 '' . 16 ''' in a horizontal or oblique direction. In the in 1 embodiment shown are high performance thermal insulation panels 10 ' . 10 '' . 10 ''' different design combined. In principle, however, in a thermal insulation composite system, only one type of high-performance thermal insulation panels 10 ' . 10 '' . 10 '' can be used or it can be high performance thermal insulation panels 10 ' . 10 '' . 10 ''' with fire protection strip 24 ' . 24 '' . 24 ' With High-performance thermal insulation panels are combined without fire protection strip. In one level are always high-performance thermal insulation panels 10 ' . 10 '' . 10 ''' arranged the same way. The fire protection strips 24 ' . 24 '' . 24 ' the individual high-performance thermal insulation panels 10 ' . 10 '' . 10 ''' border directly on each other, causing the fire bars 24 ' . 24 '' . 24 ' form a continuous ring in the horizontal direction or oblique direction, which can extend in particular to a complete circumference of a building.

LIST OF REFERENCE NUMBERS

10

High-performance thermal insulation board

12

surface

14

Hochleistungsdämmmaterial

16

recess

18

long side

20

depth

22

thickness

24

Fire protection bar

26

thickness

28

cleaning mode

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102010020394 A1 [0002]

Claims (11)

High-performance thermal insulation panel for a thermal insulation composite system, with at least one outwardly facing surface ( 12 ' . 12 '' . 12 ''' ) which is an at least substantially organic high performance insulating material ( 14 ' . 14 '' . 14 '' ) having a thermal conductivity less than 0.030 W / Km, characterized in that the surface ( 12 ' . 12 '' . 12 ''' ) at least one recess ( 16 ' . 16 '' . 16 ''' ), which is provided for receiving a non-combustible material. High-performance thermal insulation panel according to claim 1, characterized in that the recess ( 16 ' . 16 '' . 16 ''' ) parallel to a longitudinal side ( 18 ' . 18 '' . 18 ' ) runs. High-performance thermal insulation panel according to claim 1 or 2, characterized in that the recess ( 16 ' . 16 '' . 16 ''' ) a depth ( 20 ' . 20 '' . 20 ''' ) which is smaller than a thickness ( 22 ' . 22 '' . 22 ''' ) of the high-performance insulating material ( 14 ' . 14 '' . 14 ''' ). High-performance thermal insulation panel according to one of the preceding claims, characterized in that the depth ( 20 ' . 20 '' . 20 ''' ) of the recess ( 16 ' . 16 '' . 16 ''' ) at most 50 percent of the thickness ( 22 ' . 22 '' . 22 ''' ) of the high-performance insulating material ( 14 ' . 14 '' . 14 ''' ) is. High-performance thermal insulation panel according to one of the preceding claims, characterized by at least one fire protection strip ( 24 ' . 24 '' . 24 ' ), which in the at least one recess ( 16 ' . 16 '' . 16 ''' ) is used. High-performance thermal insulation panel according to claim 5, characterized in that the fire protection strip ( 24 ' . 24 '' . 24 ' ) from a solid, into the recess ( 16 ' . 16 '' . 16 ''' ) is used. High-performance thermal insulation panel according to claim 5 or 6, characterized in that the fire protection strip ( 24 ' ) a thickness ( 26 ' ) which is at most equal to a depth ( 20 ' ) of the recess ( 16 ' ). High-performance thermal insulation panel at least according to claim 5, characterized in that the fire protection strip ( 24 ' . 24 '' . 24 ' ) from one after an insertion into the recess ( 16 ' . 16 '' . 16 ''' ) cured material is formed. High-performance thermal insulation panel according to one of the preceding claims, characterized in that the high-performance insulating material ( 14 ' . 14 '' . 14 ''' ) is formed of a PUR and / or PIR foam. Thermal insulation composite system for a high-rise building with at least one high-performance thermal insulation panel ( 10 ' . 10 '' . 10 ''' ) according to any one of the preceding claims. Thermal insulation composite system according to claim 10, characterized by a plaster system ( 28 ) with a fire protection strip ( 24 ' . 24 '' . 24 ' ) of the high performance thermal insulation board ( 10 . 10 ' . 10 ''' ) is coupled.

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