DE102008036430A1 - Component for use with integrated hydrophobic, microporous silica for thermal insulation of buildings, comprises multiple shells, which are connected with assigned insulating material made of organic silicon compound - Google Patents

Abstract

The component comprises multiple shells (1,2), which are connected with an assigned insulating material made of organic silicon compound. The insulating material is glued laterally in grooves of the component and connected by the multi-shell components in force-fit manner. The covers (5) are provided, which are attached at the lower or upper side of the component.

Description

The thermal insulation of buildings, to save heating energy, has achieved a high priority against the background of dwindling fossil energy resources and the need to reduce CO ₂ emissions.

These increasing demands on an optimization of the thermal insulation protection for buildings, apply to the same extent for new buildings, as well as for existing buildings.

The The present invention relates above all to building blocks for the new building area. These can be both hollow, as well Be full building blocks.

she consist mainly of inorganic, ceramic materials, such as fired clay (bricks), concrete, glass, gypsum and natural products like natural stone, z. B. limestone. Preferably, blocks come made of brick, concrete and lightweight concrete.

It is known that the cavities of hollow building blocks ( 4 ) may be filled with porous cavity-structured insulating materials ( 8th ) (Patent Application AZ 10 2007 020 716.8 and DE 3037409 A1 and DE-OS 2825508 ). These components are referred to as hollow bricks with integrated thermal insulation and have compared to the conventional hollow bricks without filling better thermal insulation properties.

Due to the construction of the Holbausteine the insulation materials can be installed only in the individual hollow chambers of the stone ( 4 ; 8th ). This leads to better insulation properties. Because of the continuous shards construction with high thermal conductivity, but heat bridges ( 9 ), which cancel the good insulation properties of the core material in the overall system for the most part again.

So ideally would be a building block of two or more shells with a thermal barrier coating between the individual building blocks, which covers as possible the entire cross-section of the building block from the inside out so in the direction of energy flow ( 3 ; 7 ). This fails because better insulating thermal insulation materials in themselves have no sufficiently high mechanical stability to make a sufficiently strong, manageable overall component as a connecting element between the individual shells.

• • Ankern und Klammern
• • Verzurrungen und Verschnürungen, Umgürtelungen
• • Verkeilungen über Nut- und Federsysteme oder Profilleisten
• • Dübelsysteme

As already described in patent application AZ 10 2008 005 548.4, the individual shells can be held together with various frictional connections. These can be:

• • Anchors and brackets
• • lashings and lacing, girdling
• • Keying via tongue and groove systems or profile strips
• • Dowel systems

• • Bildung von Wärmebrücken möglich
• • Verbindungen sind teilweise instabil
• • Installation ist manchmal zu aufwändig
• • Installation an Stellen, die oft nicht optimal sind und daher keine oder nur geringe kraftschlüssige Verbindungen zulassen

All of these systems, however, have more or less the following disadvantages:

• • formation of thermal bridges possible
• • Connections are sometimes unstable
• • Installation is sometimes too time-consuming
• • Installation in places that are often not optimal and therefore allow little or no frictional connections

The aim of the invention is to provide the highly effective insulating effect of the hydrophobic, microporous thermal insulation between the individual building shell shells ( 1 ), as optimally as possible, over the entire brick cross section to achieve and still ensure a stable manageable total unit of the block. In order to optimally use the effectiveness of the achievable thermal insulation in relation to economy, effective combinations of highly efficient, hydrophobic, microporous thermal insulation with conventional thermal insulation systems with lower thermal insulation effects are required and possible according to the invention.

It has now been found that connection systems that are flat on the side of the shells to be connected ( 2 ), provide more effective, non-positive connections that meet the extreme requirements in the construction sector and also include an optimization of thermal insulation and ultimately result in greater cost savings than the systems already described.

Also has been found that by the invention described above Measures involving the formation of thermal bridges over the connecting elements can be largely eliminated by the choice of material and its dimensions. There are therefore materials with lower thermal conductivities than the brick shards for Commitment. The excellent insulating properties of the thermal insulation material can therefore be without significant restrictions be brought to bear. That includes the whole thing System, by using hydrophobic, microporous thermal insulation materials in Direction of the insulated energy flow remains breathable, without absorbing and storing moisture, causing mold growth prevented in the interiors or in the walls.

• • pure Kunststoffe
• • faserverstärkte Kunststoffe (GFK)
• • Polyurethane
• • Kautschuke
• • gegebenenfalls auch Holzplatten

The materials used can, for. For example:

• • pure plastics
• • fiber reinforced plastics (GRP)
• • Polyurethanes
• • rubbers
• • if necessary also wood panels

During transport and processing of the components, mechanical impairments such as vibrations, jarring, jarring, etc., which can have a negative effect on the non-positive connection, occur. To compensate for these stability disadvantages by rigid connections, elastic adhesives and / or materials are used according to the invention. The integration of the connecting elements in the grooves in the side walls of the blocks, unfavorable force effects during transport and processing of the stone through the end faces ( 4 ) of the lateral grooves largely caught. Further acting forces are due to the bonding on front and side surfaces ( 3 ) of the groove is adsorbed. In order to ensure the stability of the compounds, an elastic variant can be used both for connecting material and for the adhesive. Suitable adhesives are: I and II component adhesives, preferably adhesives based on polyurethanes.

• • höhere Stabilität durch seitliche Nuten
• • höhere Festigkeit des Bausteinsystems durch elastische Kleber und/oder Werkstoffe
• • Einbringung des Dämmmaterials auch nach der Herstellung der kraftschlüssigen Verbindung möglich

The advantages of the lateral bonding according to the invention of the frictional connections are:

• • higher stability through lateral grooves
• • higher strength of the modular system due to elastic adhesives and / or materials
• • Insertion of the insulating material also possible after the production of the non-positive connection

Before the insulation materials are introduced, the building block may be provided with a cover ( 5 ), which prevents dusting, trickling or crumbling of the insulating materials. This cover is initially attached only to the bottom of the block. Since the blocks do not know "top" or "bottom", here, for better understanding, the side from which a filling of the cavities takes place is referred to as "top", the opposite side as "bottom surface" or "bottom". After filling with the insulating material, the top of the block can be covered.

The Covering material has a lower coefficient of thermal conductivity than the brick shards, high strength and is in material thicknesses between 0.5 and 5.0 mm, preferably with 1.0 mm thickness used.

The cover can cover both the entire block bottom surface, or the block top side, and preferably a partial area (FIG. 1 ) of the block bottom or the block top side. The cover size is inventively chosen so that it completely covers the zones with integrated insulation. In both cases, the block is provided at the intended locations with a groove for receiving the seal or already manufactured in the manufacture in a thickness that ensures no attachment of the seal of the total dimensions allowed of the block. The cover can, but need not, additionally strengthen the non-positive connection (2) of the two brick shells.

The Cover can also be used as an aid to bring in the insulation materials be used by compacting and pressing in the block A perforation is advantageous according to the invention the cover, which is the ventilation and compression of insulating materials facilitated and optimized.

All methods described require that the insulation materials of the top of the stone are introduced. It is also possible, the insulation via a block side introduce when the non-positive connection on one side only after filling with insulating material is attached.

One Another advantage of the cover is that in addition to bulk solids (which have the disadvantage of being inhomogeneous and therefore of thermal bridging tend), according to the invention integrated thermal insulation molding which can have very low bulk densities. These Bulk densities are chosen so low according to the invention, that they still have the intrinsic structure of the insulating body maintained. Due to the low bulk densities can Lambda values <0.015 W / mK achieved at the same time, due to the reduced use of raw materials, has a cost-damaging effect.

Around for the building block with integrated thermal insulation to achieve sustainable high thermal insulation Highly efficient, inorganic insulating materials are used. According to come as core materials thermal insulation materials based on microporous silicic acids with organosilicon Compounds made permanently resistant to water were used. In addition, there are so-called opacifiers, fibers and / or others Fillers. These are thermal insulation materials generally as microporous thermal insulation materials known (patent application: AZ: 10 2007 020 716.8). According to the invention these in compressed form (plates or shaped bodies) by addition of organic silicon compounds immediately before compaction, or the compression of the mixture.

The above-mentioned technology for frictional connection of the individual building blocks on the core insulation, according to the invention is suitable for hydrophobic, microporous thermal insulation panels with other conventional Wär to combine medical materials.

The thermal insulation systems used in the multi-layered building block are used both individually and in combination with other thermal insulation materials. These include, for example:
inorganic fiberboard, perlite, vermiculite, silicate foam, but here also both combinations with each other and for the insulation between the shells are possible.

The Production of a multi-shell hollow brick with integrated Thermal insulation between the shells takes place according to the invention in the kind that the respective Dämmmaterialen to a shell of the block and a counter shell of the block is pressed to the desired overall size.

at A vacuum insulated insulation can also be over the shells of the insulation system, with adhesives fixed a connection become.

After merging the component shells and the insulating material, the module shells are glued together in the fixed state by two-dimensional connection systems on both sides of the module ( 2 ) and leave in this condition until the bond is stable. It is also possible first to connect the module shells until the system is stabilized and then the insulation is introduced. The already described coverage of the bottom surface then takes place before introduction of the insulating material when bulk materials or insulation materials are to be introduced with low density.

In In all cases, the top of the module is covered naturally after filling with insulating materials, unless a side filling, as already described will be carried out, in which case coverage of the and bottom of the building block before filling.

The above-described technologies for the insulation of multi-skin Blocks become meaningful and according to the invention also for the insulation of hollow building blocks with hydrophobic, microporous Insulating materials used with organosilicon compounds were made water resistant.

Especially this applies both to the attachment of covers Bottom and / or top of the module as filling aid, or as a holder for the insulating material, as well z. B. for insulation materials with low density.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• DE 3037409 A1 [0005]
• - DE 2825508 [0005]

Claims (8)

Building block with integrated hydrophobic microporous silica as thermal insulation, characterized in that in multi-shell building blocks, the shells of the block, together with the insulating material used, are held together by lateral, bonded in grooves of the block, frictional connections. Building block with integrated hydrophobic, microporous Silica as thermal insulation according to claim 1. characterized in that both the adhesive and / or the connecting elements are elastic. Building block with integrated hydrophobic, microporous Silica as thermal insulation according to claim 1. and 2. characterized in that at the bottom and / or top of the building block covers are attached. Building block with integrated hydrophobic, microporous Silica as thermal insulation according to claim 3. characterized in that these covers be perforated can. Building block with integrated hydrophobic, microporous Silica as thermal insulation according to claim 1 to 4, characterized in that the thermal insulation materials used permanently hydrophobicized with organic silicon compounds. Building block with integrated hydrophobic, microporous Silica as thermal insulation according to claim 1 to 5, characterized in that the hydrophobing of the mixture preferably immediately before compacting or pressing the Mixture takes place. Module with integrated hydrophobic microporous silica as thermal insulation according to claim 5 and 6, characterized in that the thermal insulation materials used have low densities (80-180, preferably 90-150 kg / m ³ ) have. Building block with integrated hydrophobic, microporous Silica as thermal insulation, according to claims 3rd to 7th characterized in that the cover and the filling is also used for hollow bricks.