DE102011113287B4 - Thermal insulation module and method for its production - Google Patents

Abstract

Thermal insulation module (2) with a first calcium silicate layer (4) and a second calcium silicate layer (6) and between the first calcium silicate layer (4) and the second calcium silicate layer (6) positionable thermal insulation (W) in a receiving space (12) between the calcium silicate layers (4, 6) is limited, which is bounded by a frame assembly (8), via which the first calcium silicate layer (4) with the second calcium silicate layer (6) is connectable and which is also made of calcium silicate, characterized in that the frame assembly ( 8) is at least partially formed integrally with two calcium silicate layers (4, 6), wherein the receiving space (12) is milled out of a cuboidal starting element of calcium silicate pocket-like manner from one edge side (16).

Description

The invention relates to a thermal insulation module, in particular for the production of an internal insulation or a Außenwärmedämmverbundes on a building wall according to the preamble of claim 1, and a method for its production and a thermal insulation, which is made using at least one such heat insulation module. In this case, the thermal insulation module has a first calcium silicate layer and a second calcium silicate layer as well as thermal insulation, which can be arranged between the first calcium silicate layer and the second calcium silicate layer.

Such thermal insulation modules can be mounted in particular on the inner walls of buildings and allow through the middle insulating layer in a known manner a better saving of heat energy and at the same time by the water-absorbent outer plates high intake of water and water vapor, which in turn creates an improved indoor climate and the formation of Surface moisture and consequent mold growth can be avoided.

Out WO 2010/009713 A2 a system for thermal insulation and / or wall renovation of buildings is known in which two thermal insulation boards made of calcium silicate with the interposition of a thermal insulation board with particularly low thermal conductivity are provided. The three thermal insulation panels are assembled in a sandwich type, where they are attached to each other for example by means of a vapor diffusion-open adhesive.

In this known thermal insulation model, depending on the application, a material for the average thermal insulation board can be selected, which ensures either by its high capillary high moisture transport between the two outer calcium silicate plates or has a particularly low thermal conductivity.

In many applications of such thermal insulation modules, in particular in the internal insulation of building exterior walls, it is desirable to achieve both a high thermal insulation capacity to minimize the energy needs of a building, as well as to ensure a sufficiently high moisture transport between the outer thermal insulation panels, for example, on an inside of the perturbing accumulated condensation wall of this building wall and can deliver it to the room air.

If, however, a material with particularly low thermal conductivity is used in the known thermal insulation modules for the middle thermal insulation board, this has the consequence, with the typically low capillary activity of these materials, that almost no moisture transport can take place between the outer thermal insulation boards, since this is prevented by conventional thermal insulation materials, such as For example, airgel mats, foams or rock wool, is prevented. In addition, the moisture transport is also made more difficult by the adhesive layers between the middle thermal insulation board and the outer thermal insulation panels. In addition, in such thermal insulation modules, only heat insulating materials for the middle thermal insulation board can be used, which have sufficient strength for use in the sandwich type.

WO 87/06966 A1 describes a ship-use panel comprising a frame made of calcium marine (Cape Marine) board elements which encloses a receiving space in which inter alia a thermal insulation material is accommodated. Both sides of the receiving space are closed by an inner layer of a laminate plate, which are also formed from calcium silicate.

DE 10 2010 044 789 A1 shows a thermal insulation board in which the frame assembly of calcium silicate is either installed between the calcium silicate plates or formed integrally with one of the plates.

Thereafter, the heat insulation in a receiving space between the calcium silicate layers is accommodated, which is limited by a frame assembly. By way of the frame arrangement, the first calcium silicate layer is connected to the second calcium silicate layer, wherein the frame arrangement is likewise made of calcium silicate. Due to the high capillary conductivity of the calcium silicate can thus take place via the frame assembly moisture transport from one of the calcium silicate layers to the other, for example, to transport a incurred on a building wall moisture away from it and through the cross section of the heat insulation module and to be able to deliver to the room air.

The object of the invention is to simultaneously enable a better moisture transport between the calcium silicate layers in a generic thermal insulation module with very low thermal conductivity.

This object is achieved by a thermal insulation module having the features of claim 1. The frame assembly is at least partially formed integrally with two calcium silicate layers. A corresponding shaping of the Calcium silicate can be done by milling the receiving space from an example cuboidal output element made of calcium silicate from one edge side. In this way, a particularly good moisture transport between the calcium silicate layer and the frame assembly is guaranteed. At the same time it is possible by means of the frame assembly, a particularly suitable insulation material loose, that is, in particular without bonding to take in the thermal insulation module. In this way, a particularly large variety of insulation materials can be used.

In a particularly advantageous embodiment, the frame arrangement delimits the receiving space parallel to the main extension planes of the calcium silicate layers in four directions. As a result, the thermal insulation can be completely fixed in its position solely by the frame assembly. In addition, in the case of a fully closed embodiment of the frame assembly, the use of a free-flowing thermal insulation material, such as an airgel used.

It is advantageous if the receiving space forms at least one, preferably two or three substantially cuboidal cavity. As a result, a particularly simple assembly of the receiving space, in particular with a mat-shaped thermal insulation element or two or three thermal insulation elements is possible. The thermal insulation elements must be pre-dimensioned here only with the corresponding outer dimensions and inserted into the respective cavities of the receiving space.

Advantageously, the frame assembly is at least partially connected or connectable by means of a vapor diffusion-open adhesive with the calcium silicate layers. In this way, even with a bonded connection between the calcium silicate layer and the frame assembly, a sufficiently high moisture transport between the elements concerned can be ensured.

Alternatively, it is advantageous if the frame assembly is at least partially connected or connectable by means of mechanical connection means, that is, in particular via means of a screw, dowel, rivet or nail connection, with the calcium silicate layers. In this way, the respective elements can be applied directly to each other or biased against each other, whereby a substantially unhindered moisture transport over the contact area can be ensured away.

It is in any case favorable if the frame arrangement occupies a share area of 10 to 15% with respect to a total base area of the thermal insulation module. With such an area ratio of the frame arrangement, depending on the selection of the thermal insulation used, on the one hand a very low average thermal conductivity of 0.030 W / mk or even 0.020 W can be maintained and at the same time a relatively high moisture transport from one outside to the other outside ensured.

In a particularly advantageous embodiment, the calcium silicate layers are preassembled the frame assembly and arranged in the receiving space thermal insulation. As a result, a particularly accurate processing of the thermal insulation module is possible, in particular a particularly good filling of the cavities of the receiving space by the thermal insulation. In this way, the thermal insulation module can be used particularly easily and conveniently for the production of an interior or exterior insulation of a building wall, wherein a predetermined thermal conductivity and a predetermined capillary activity in the production of the respective insulation can be maintained relatively easily.

Furthermore, the stated object is achieved by a method for producing a thermal insulation module in one of the aforementioned embodiments, wherein in a first step, the receiving space is produced by milling the corresponding cavities of a calcium silicate plate. The cut-out is made from one edge side of the calcium silicate board. In a second step, the thermal insulation is introduced into the receiving space and closed in a third step, the receiving space with the thermal insulation received therein. As a result, a relatively simple and exact one-piece production of the frame assembly with at least one of the calcium silicate layers is possible.

Advantageously, the receiving space is closed in the third step by a further frame member made of calcium silicate. In this way, an essential part of the frame assembly can be made together with two calcium silicate layers of a single calcium silicate plate and sealed by means of another calcium silicate element, which ensures a particularly high capillary activity between the two calcium silicate layers.

Furthermore, the stated object is achieved by a thermal insulation of a building wall produced by using at least one of the above-mentioned thermal insulation modules, wherein at one edge surface of the thermal insulation module is provided on the building wall side, a first adapted calcium silicate layer glued in between the edge surface and a end strip, on which an adapted thermal insulation is applied, in this case in a through the edge surface, the end strip, the first adapted calcium silicate layer and a room side between the edge side and the end strip glued in second adjusted calcium silicate layer is accommodated in a limited receiving space. In this way, regardless of whether it is provided by an internal insulation or as part of a thermal insulation composite system, for example, for the outside of a building wall, the thermal insulation can be particularly easily and accurately adapted to the respective dimensions of the relevant building wall.

In the figures, an exemplary embodiment of the invention is shown. Show it:

1 an exploded perspective view of a Wärmedämmmodules invention and

2 a sectional view of a using the thermal insulation element according to 1 produced thermal insulation of a building wall.

1 shows a thermal insulation module 2 , which is a closed first calcium silicate layer 4 and a parallel second calcium silicate layer spaced therefrom 6 which has a frame arrangement 8th connected to each other. The frame arrangement 8th here has several frame elements 10 having a substantially rectangular profile, whose main extension direction is parallel to the main extension plane of the two calcium silicate layers 4 . 6 lies. The frame arrangement 8th is also made of calcium silicate and thus has as well as the two calcium silicate plates 4 . 6 high capillary activity. This limit the frame elements 10 several cuboidal cavities, one between the two calcium silicate layers 4 . 6 arranged recording room 12 form.

In the in 1 illustrated embodiment of the thermal insulation module 2 are the frame elements 10 and the calcium silicate layers 4 . 6 from a single calcium silicate board 14 made in the cavities of the receiving space 12 from a side edge 16 her pocket-like means of a conventional milling tool (not shown) are milled. In this way, the frame elements 10 and the calcium silicate layers 4 . 6 formed in one piece and thus also at the transitions undisturbed capillary activity. As an alternative to milling, the one-piece design of the frame assembly 8th and the calcium silicate layers 4 . 6 also be obtained by molding a corresponding molding with calcium silicate.

The recording room 12 serves to accommodate a thermal insulation W, for example, by mat-shaped thermal insulation elements 18 may be formed in the cavities of the receiving space 12 be pushed in, as in 1 represented by mounting arrows M1. Alternatively, it would also be conceivable, the recording room 12 For example, to fill with a pourable or foamable thermal insulation W (not shown). In particular, airgel nonwoven mats, silicate aerogels, nanogels, fumed silica, resole foam, vacuum-packed highly disperse silica, vacuum panels or rockwool are provided as possible insulation materials of the thermal insulation. In this case, when using a diffusion-open thermal insulation W, a mean water vapor diffusion resistance coefficient μ of at most 3 can be maintained, so that a sufficient water vapor diffusion over the complete cross section of the thermal insulation module 2 is guaranteed.

In any case, the cavities of the receiving space 12 After the heat insulation W is loosely received in these, as shown by mounting arrow M2, by means of another frame member 10A closed, which is also made of calcium silicate. For this purpose, the further frame element 10A on the edge side 16 by means of mechanical connection means 20 set, which are exemplified as screws. Alternatively, it would also be conceivable that the further frame element 10A by other mechanical connection means 20 how nails, rivets or dowels are laid or by means of a bond on the edge side 16 In particular, an open-pored adhesive layer should be used in order to enable a certain moisture transport in the region of the bond can.

By attaching the further frame element 10A be all cavities of the receiving space 12 parallel to the main extension planes of the calcium silicate layers 4 . 6 limited in all four directions and thereby at the same time the absorbed therein insulation W completely fixed in position.

This is how the thermal insulation module stands 2 ready pre-assembled available and can, for example, to produce a thermal insulation 22 , in particular on the inside of a building wall 24 used as in 2 shown.

In any case, the frame arrangement will take 8th with the frame elements 10 . 10A based on a through the entire thermal insulation module 2 spanned total base area GF preferably a proportion area AF of 10 to 15%, in particular 13%, whereby despite the receiving spaces 12 or the thermal insulation W received therein an effective transport of moisture from one of the calcium silicate layers 4 . 6 can be guaranteed to each other.

When selecting a suitable thermal insulation W in terms of material and thickness, the thermal insulation module 2 As a result, a mean thermal conductivity λ of at most 0.030 and preferably 0.020 W / mK can be achieved without difficulty.

To the building insulation 22 according to 2 to produce several of these thermal insulation modules 2 side by side and one above the other on the relevant building wall 24 fixed, for example by means of an adhesive layer 28 , To do the building wall 24 regardless of their dimensions over the entire surface with the thermal insulation 22 to provide, is a ceiling / wall finish 30 can be produced, which can be adapted individually to the local conditions.

In this ceiling / wall closure 30 is between an outer edge surface 32 of the respective adjacent prefabricated Wärmedämmmodules 2 and one of the thermal insulation 22 bounding ceiling / wall 34 attachable end bar 36 whose width is the width of the edge surface 32 corresponds to a first adapted calcium silicate layer 38 glued. In the resulting adapted open recording room 40 Then, an adapted heat-insulating element Wa is introduced, which has the same material properties and the same thickness as the thermal insulation W of the remaining thermal insulation 22 having. Subsequently, the adapted recording room 40 by means of a second adapted calcium silicate layer 42 closed, which is also between the edge surface 32 and the end bar 36 is glued.

In this way, by means of the thermal insulation modules 2 For example, a full-surface insulation or part of a Außenwärmedämmverbundsystems produced, the insulation has a good overall capillary and hygroscopic conductivity. The capillary water absorption of the calcium silicate is about 270% by mass. In addition, the thermal insulation module ensures 2 with a maximum water vapor diffusion resistance coefficient μ of the calcium silicate of at most 3.0 a relatively high water vapor permeability and also has a high fire protection class.

Claims (10)

Thermal insulation module ( 2 ) with a first calcium silicate layer ( 4 ) and a second calcium silicate layer ( 6 ) as well as between the first calcium silicate layer ( 4 ) and the second calcium silicate layer ( 6 ) positionable thermal insulation (W) in a receiving space ( 12 ) between the calcium silicate layers ( 4 . 6 ) which can be accommodated by a frame arrangement ( 8th ), over which the first calcium silicate layer ( 4 ) with the second calcium silicate layer ( 6 ) and which is also made of calcium silicate, characterized in that the frame assembly ( 8th ) at least partially in one piece with both calcium silicate layers ( 4 . 6 ) is formed, wherein the receiving space ( 12 ) from a cuboidal starting element made of calcium silicate from an edge side ( 16 ) is pocket-like milled out. Thermal insulation module according to claim 1, characterized in that the frame arrangement ( 8th ) the recording room ( 12 ) parallel to the calcium silicate layers ( 4 . 6 ) in four directions. Thermal insulation module according to claim 1 or 2, characterized in that the receiving space ( 12 ) forms at least one substantially cuboidal cavity. Thermal insulation module according to one of claims 1 to 3, characterized in that the frame arrangement ( 8th ) at least partially by means of a vapor diffusion-open adhesive with the calcium silicate layers ( 4 . 6 ) is connectable. Thermal insulation module according to one of claims 1 to 4, characterized in that the frame arrangement ( 8th ) at least partially by means of mechanical connection means ( 20 ) with the calcium silicate layers ( 4 . 6 ) is connectable. Thermal insulation module according to one of claims 1 to 5, characterized in that the frame arrangement ( 8th ) occupies a proportion area (AF) of 10 to 15% with respect to a total base area (GF) of the thermal insulation module. Thermal insulation module according to one of claims 1 to 6, characterized in that the calcium silicate layers ( 4 . 6 ) the framework ( 8th ) and in the recording room ( 12 ) arranged thermal insulation (W) are pre-assembled. Method for producing a thermal insulation module according to one of claims 1 to 7, characterized in that in a first step the receiving space ( 12 ) by milling a calcium silicate plate ( 14 ), wherein the cut-out from one edge side ( 16 ) of the calcium silicate board ( 14 ) is made, in a second step, the thermal insulation (W) in the receiving space ( 12 ) and in a third step the receiving space ( 12 ) is closed with the thermal insulation (W) received therein. Manufacturing method according to claim 8, characterized in that the receiving space ( 12 ) in the third step by a further frame element ( 10a ) is sealed from calcium silicate. Thermal insulation of a building wall, which is produced using at least one thermal insulation module according to one of claims 1 to 7, characterized in that on an edge surface ( 32 ) of the thermal insulation module ( 2 ) an adapted ceiling / wall termination ( 30 ) is provided, the Gebäudewandseitig one between the edge surface ( 32 ) and a closing bar ( 36 ) pasted first adapted calcium silicate layer ( 38 ), on which an adapted thermal insulation element (Wa) is applied, which in this case in a through the edge surface ( 32 ), the end bar ( 36 ), the first adapted calcium silicate layer ( 38 ) and a room side between the edge side ( 32 ) and the end bar ( 36 ) glued in second modified calcium silicate layer ( 42 ) Limited Adapted Reception Area ( 40 ) is recorded.

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