WO2014044709A1

WO2014044709A1 - Wall structure for interior insulation systems having laid thermally insulating panels with variable gap sizes

Info

Publication number: WO2014044709A1
Application number: PCT/EP2013/069375
Authority: WO
Inventors: Günter Kratel
Original assignee: Evonik Industries Ag
Priority date: 2012-09-22
Filing date: 2013-09-18
Publication date: 2014-03-27
Also published as: DK2898154T3; EP2898154A1; EP2898154B1

Abstract

The invention relates to a wall structure for interior insulation systems having thermally insulating panels, wherein the thermally insulating panels are fastened to an existing or newly attached layer having capillary action on site on the wall side with a defined gap width and the gaps are filled up with a layer having capillary action, and the side of the thermally insulating panels facing the room interior are also covered with a layer having capillary action, and thus the thermally insulating panels are surrounded on all sides by said layers having capillary action.

Description

Wall construction for interior insulation systems with installed thermal insulation panels with variable joint distances

Thermal insulation is becoming increasingly important against the background of rising energy costs and the higher demands placed on energy savings

Meaning too. A new generation of thermal insulation materials, are the

Microporous thermal insulation materials based on pyrogenic silicas or silica aerogels. These are characterized not only by their incombustibility and physiological safety, but also by their high level of safety

Thermal insulation effect in the range of minus 200 ° C up to 1000 ° C from.

Microporous plates based on fumed silica, such as. As described in EP-A-1988228 and / or aerogels, opacifiers, reinforcing fibers and optionally further additives such as precipitated silicas or fly ash are considered prior art and are available in numerous

Applications, also successfully used as core material in vacuum insulation panels (VIP).

A serious disadvantage, however, is that these insulation materials, in contact with liquid water their structure and thus among others their

Lose thermal insulation properties irreversibly. A subsequent complete drying can not restore the original state. To compensate for this disadvantage were microporous insulation materials and

Insulating boards developed which are hydrophobic, so water repellent. For example, EP-A-1988228 and DE-A-102010005800 describe processes for producing hydrophobic thermal insulation panels based on pyrogenic silicas.

A disadvantage of these water-repellent insulation boards is that they have no capillary-active properties, e.g. Moisture (condensate) capillary through the thermal barrier layer to be able to deliver to the interior. This is absolutely necessary for the sustainable functioning of an interior insulation system. In the published patent application DE-U-202009008493 z. B.

described that the capillary effect is achieved with a heat-insulating panel, by inserting breakthroughs in the thermal insulation board which are filled with capillary-active substances.

Other thermal insulation panels, z. B. DE-A-102010044789 are designed so that between a capillary active cover plate and a capillary active (boundary layer) support plate heat insulation elements with a lower

specific thermal conductivity are built into free spaces so that they are surrounded by capillary-active webs, which connect the cover and carrier plates together.

Disadvantages with this type of thermal insulation composite panels are that the ratio of capillary-active surface to thermal insulation surface is always the same, d. H. the size of the capillary-active surface so not individually the different

room climate conditions can be adjusted. On extreme

Conditions such as B. in wet rooms, you can therefore only react with great effort. Another disadvantage is that when blanks on site, possibly the capillary active part must be discarded and thus moisture in the masonry can arise. The production of this type of composite panels is also costly.

The object of the invention is therefore to achieve a slimmer internal insulation with the best possible thermal insulation by capillary active,

open to water vapor diffusion areas for a recording of

Room humidity in the wall allows, on the other hand, a return of liquid water (condensate) by capillarity and evaporation into the room guaranteed. At the same time an uncomplicated, cost-effective production of the thermal insulation board, as well as a simple attachment of the insulation system to be given locally.

The technical task is by a wall construction for a

Innendämmungssystem solved with thermal insulation panels, the wall structure is characterized in that the thermal insulation panels with defined Joint width wall side are fixed on site on an existing or newly attached capillary active layer and filled the joints with a capillary active layer, as well as the inside of the room facing side of the

Thermal insulation panels are covered with a capillary-active layer and are thus surrounded on all sides by these capillary-active layers.

Capillary-active layer here means a layer with a

Water absorption coefficient w of> 0,5 kg / m'h ^0,5 .

The joints are filled with the help of capillary-active, preferably heat-insulating grout, mortar or plaster column-free. Towards the room side, the thermal insulation panels are also covered with a capillary-active, preferably heat-insulating layer, so that the thermal insulation panels are surrounded on all sides by the layers described above.

According to the invention, an effective thermal insulation, combined with sufficient return of moisture, present as condensate, by capillarity, whereby the choice of the joint width, in combination with the joint mortar, determines the capillary active performance. Vapor barriers, such as these are absolutely necessary in the classic non-capillary active insulation systems, are eliminated.

The capillary-active layer is preferably designed as a heat-insulating layer. The capillary-active layer may consist of mortar or plaster, possibly reinforced with tissues, or consist of plates. In a special

Embodiment, the capillary-active layer comprises calcium silicate plates. The calcium silicate boards used according to the invention preferably have a density of 250-380 kg / m ³ . According to the present invention, the joints are filled with a capillary-active layer. The width of the joints is preferably 5 to 30 mm, more preferably 8 to 20 mm.

The material of the capillary-active layer preferably has an average porosity of 50-70% by volume. In a particular embodiment of the invention, the joints comprise strips of calcium silicate or they consist thereof.

The water vapor diffusion resistance number of the joint material is preferably 5-20. The specific thermal conductivity of the joint material is preferably <0.25 W / mK, particularly preferably <0.15 W / mK and very particularly preferably <0.10 W / mK.

Preferably used for thermal insulation panels with a low specific thermal conductivity. These can be organic

Thermal insulation panels, such as polyurethane or vacuum insulation panels (VIP) be. For polyurethane and vacuum insulation panels, it should be noted that these are not permeable. To be favoured

inorganic thermal insulation panels based on microporous silica used. Particularly advantageous in this case is pyrogenically prepared silica. The fumed silica is usually obtained by flame hydrolysis. In this method, a vaporized or gaseous hydrolyzable silicon halide is reacted with a flame formed by combustion of hydrogen and an oxygen-containing gas. The combustion flame thereby provides water for the hydrolysis of the silicon halide and sufficient heat for the hydrolysis reaction. A silica produced in this way is called fumed silica. In this process, primary particles are initially formed, which are almost free of internal pores. During the process, these primary particles merge via so-called "sintering necks" into aggregates which, on account of their

three-dimensional, open structure are macroporous. Due to this structure, fumed silica powders are ideal thermal insulation materials because the aggregate structure provides sufficient mechanical stability

Heat transfer through solid-state conductivity across the "sintered necks" is minimized and produces a sufficiently high porosity.The best results are obtained when the thermal insulation board

hydrohobed, fumed silica. In general, the thermal insulation panels contain fumed silica or one or more opacifiers. These include carbon blacks, titanium oxides,

Silicon carbides, zirconium oxides, ilmenites, iron titanates, iron oxides, zirconium silicates and manganese oxides. A mixture comprising fumed silica and

Turbidity agent usually contains 30 to 95 wt .-% of fumed silica and 5 to 70 wt .-% opacifier, based on the sum of pyrogenic

Silica and opacifiers.

The specific thermal conductivity of the thermal insulation panels is preferably less than 0.04 W / m-K, particularly preferably less than 0.025 W / m-K. The thickness of the thermal insulation panel is preferably 20 to 70 mm, particularly preferably 30 to 50 mm.

Through the joint mortar, or the plasters, the thermal insulation boards are installed and stabilized firmly and free of air bubbles in the composite system. Preferably, the mortars masses or plasters, light mortar with high porosity and thus be low specific thermal conductivity. However, the capillary activity must not be impaired. Therefore, the diffusion activity of the entire system is controlled by the mortar and the joint width. In addition VIPs must not be doweled through the core or the edge foil. But anchorages are possible over the joints, with large plates. In order to ensure optimum bonding of hydrophobic thermal insulation panels with the joint mortars and plasters present as aqueous systems, these can be provided with a hydrophilic surface, as described in DE-A-102010046678. Likewise, a hydrophilic lamination as described in DE-A-102010046684 is possible. Alternatively, the

Heat insulation panels are also wrapped in perforated shrink films. The perforation serves U. a. the preservation of the diffusion openness.

The fixation of the thermal insulation panel preferably comprises an adhesive having a water vapor diffusion resistance number of 10 -100, more preferably 15-50. The capillary-active layer located on the interior side facing the thermal insulation panel, preferably has a

Water vapor diffusion resistance number of 5 to 30 and includes mortar, preferably in a thickness of 10 mm - 30 mm or calcium silicate plates with a thickness of 10 - 30 mm, preferably with a density of 250 - 380 kg / m ³ .

Basically, the thermal insulation panels can be laid freely, e.g.

offset from each other or as is the particular local situation, for. B. at soffits required.

A multi-layered construction of thermal insulation panels and capillary-active layer can be repeated as needed to the inside of the room. The system has the following advantages over conventional systems:

a) simple attachment of the individual thermal barrier coatings on site

b) a slim, space-saving system,

c) no complicated and costly production of

Exterior insulation plates

d) uncomplicated cutting, laying and grouting, as well as assembly of the system on site even at reveals

e) the system is largely airtight due to the full-surface attachment of each layer, even on uneven walls. This causes air circulation and thus the formation of thermal bridges and thus the risk of

Mold formation excluded.

f) individual combination of the insulation thicknesses and permeable surfaces, depending on the climatic conditions of the room or the use of space (eg damp rooms), it is possible to determine the gap width (corresponds to the capillary active area performance) between the thermal insulation panels

To vary on-site performance. This is supported by

Simulation calculations with material-specific characteristic values

g) when using purely inorganic materials, such as hydrophobic, microporous thermal insulation panels, the system does not contain a fire load a laying of electrical wiring or piping is possible without destroying the insulation layers in the system joints. The structure of the thermal insulation system on the wall to be insulated can be done in different variants and is as follows:

The inner wall (1) to be insulated optionally receives a mineral

Sealing mud (MDS). On this prepared wall, the first capillary-active mortar layer, which can also serve as a leveling layer, is applied (2).

Variant A) (FIG. 1):

On the capillary-active mortar layer (2), the heat insulation panels (3) are fixed over the entire surface so that individually wide joints (4) arise between the individual plates. Fixed thermal insulation panels and joints are filled with capillary, preferably heat-insulating plaster (5) and covered. The

Fixation is done by pressing the thermal insulation board in the not yet set mortar layer, or by adhesive (7) on the set

Mortar layer and / or anchor (8) in the existing wall through the mortar layer.

Variant B) (FIG. 2):

On the capillary active mortar layer (2) become capillary active plates

preferably glued from calcium silicate (9) without joints (7) and / or anchored (8). On the resulting wall surface according to variant A) the

Thermal insulation panels (3) and plasters (5) applied.

Variant C) (FIG. 3):

On the capillary-active mortar layer (2) according to alternative B)

capillary-active plates preferably made of calcium silicate (9) without joints attached. On the resulting wall surface according to variant B) the

Heat insulation panels (3) fixed. The resulting joints are with

capillary-active, preferably heat-insulating grout (10) filled flush. Alternatively capillary-active, in length, width and height of the joints adapted strips, preferably glued from calcium silicate. In turn, plates, preferably of calcium silicate (9a), are glued and / or anchored to the surface thus formed, and the space-side surface then becomes

optically designed (1 1). Variant D) (FIG. 4):

According to variant A) are on the capillary active mortar layer (2) the

Heat insulation panels (3) over the entire surface fixed so that between the individual plates individually wide joints (4) arise. According to variant C), the resulting joints with capillary, preferably heat-insulating

Grout mortars or strips (10) filled flush, alternatively capillary, in length, width and height of the joints adapted strips, preferably made of calcium silicate glued. On the resulting surface will turn

Plates, preferably made of calcium silicate (9a) glued or anchored, the room-side surface is then designed visually (1 1).

The capillary-active plates and strips are fixed with capillary-active adhesives (7) on the respective lower layer. For thermal insulation panels with hygrically active, so hydrophilic surface and hydrophobic core, simple adhesives, e.g. Tile adhesive can be used. With hydrophobic surface of the

Thermal insulation panels, appropriate active adhesive can be used for attachment, which contain a sufficient amount of wetting agents and thus allow the wettability of the surface of the hydrophobic thermal insulation panels.

The adhesives used are said to have slightly higher diffusion resistances than the thermal insulation boards, so that they can be effective as a water vapor barrier. Any condensate is then formed on the adhesive surface and is returned by the capillary-active systems.

Optionally, both the hydrophobic thermal insulation panels and the capillary-active thermal insulation panels with dowels, preferably made of plastic and flat anchors in the masonry can be additionally attached (8). To further

Stabilization of the overall system, the plasters can be reinforced with tissue.

Claims

claims

1 . Wall construction for interior insulation system with thermal insulation panels, characterized in that

the thermal insulation panels are defined with a defined joint width on site on an existing or newly attached capillary active layer and filled the joints with a capillary active layer, as well as the inside of the room facing side of the thermal insulation panels are covered with a capillary active layer and thus on all sides of these capillary active layers are surrounded.

2. Wall structure for indoor insulation system with thermal insulation panels according to claim 1, characterized in that

the capillary-active layer is a heat-insulating layer.

3. Wall construction for interior insulation system with thermal insulation panels

according to claims 1 or 2, characterized in that

the capillary-active layer consists of mortar or plaster or of plates.

4. Wall construction for interior insulation system with thermal insulation panels

according to claim 3, characterized in that

the plates are calcium silicate plates.

5. Wall construction for interior insulation system with thermal insulation panels,

according to claims 1 to 4, characterized in that

the width of the joints is 5 - 30 mm.

6. Wall construction for interior insulation system with thermal insulation panels,

according to claims 1 to 5, characterized in that

the mean porosity of the joints is 50-70% by volume.

7. Wall construction for interior insulation system with thermal insulation panels,

according to claims 1 to 6, characterized in that

the joints comprise strips of calcium silicate.

8. Wall construction for interior insulation system with thermal insulation panels, according to claims 1 to 7, characterized in that

the water vapor diffusion resistance number of the joint material is 5-20 and the specific thermal conductivity is <0.25 W / mK.

9. Wall construction for interior insulation system with thermal insulation panels

according to claims 1 to 8, characterized in that

the thermal insulation boards inorganic plates based on pyrogenic

Silica are.

10. Wall construction for interior insulation system with thermal insulation panels,

according to claims 1 to 9, characterized in that the

Thermal insulation panels consist mainly of hydrophobic, fumed silica.

1 1. Wall construction for interior insulation system with thermal insulation panels,

according to claims 1 to 10, characterized in that

the thermal insulation panels contain one or more opacifiers.

12. Wall construction for interior insulation system with thermal insulation panels,

according to claims 1 to 1 1, characterized in that

the thermal insulation panels have a specific thermal conductivity of less than 0.04 W / m-K.

13. Wall construction for interior insulation system with thermal insulation panels,

according to claims 1 to 12, characterized in that

the thickness of the thermal insulation board is 20 to 70 mm.

14. Wall construction for interior insulation system with thermal insulation panels,

according to claims 1 to 13, characterized in that the

Thermal insulation panels are vacuum insulation panels.

15. Wall construction for interior insulation system with thermal insulation panels,

according to claims 1 to 14, characterized in that the fixation of the thermal insulation board an adhesive with a

Water vapor diffusion resistance number of 20 -100 includes.

Wall construction for interior insulation system with thermal insulation panels, according to claims 1 to 15, characterized in that

the capillary-active layer, which is located on the inside of the room facing side of the thermal insulation board, a

Having a water vapor diffusion resistance number of 5 to 30 and comprising mortar or calcium silicate boards each having a thickness of 10 to 30 mm or more.

Wall construction for interior insulation system with thermal insulation panels, according to

Claims 1 to 16, characterized in that

to stabilize the wall system anchors are used.