DE4107430C2 - Component - Google Patents

Description

The invention relates to a component according to the preamble of claim 1.

The physical requirements for building construction ver used components or assemblies are designed in in practice quite complex. They refer to static properties, heat and sound insulation properties, resilience and resistance to about environmental influences of any kind, processability etc. In addition, there is an increasing focus preventive fire protection. So should the building structure, i.e. H. External walls and ceilings, Not only design floors and partition walls in the event of a fire be stable - none of these should be toxic gases are released.  

From DE-GM 89 01 791.9 a building block or a wall element is known which is characterized by several successive layers perpendicular to the wall plane of different material properties. These layers consist on the outside of a concrete-like, open-pore foam and with material such as expanded clay, expanded glass, slag, sintered pumice or the like lean material, between which a barrier layer acting as a vapor barrier made of a closed-pore foamed inorganic material such as. B. foam glass or a foamed th organic plastic, such as. B. polystyrene or polyurethane is arranged. The density of the emaciated material is set at approximately 0.4 gcm ^-3 . The individual layers are interconnected using a rubber-elastic, cement-containing adhesive, the cement of which is bound by polymeric components. Although this known component has a certain resistance due to the layer of inorganic foam material on the outside, even in the event of a fire - in the case of extreme external heat effects, however, at least the composite effect between the individual layers given by the rubber-elastic adhesive could be impaired.

For purposes of new construction, but also for renovation or Removal of buildings are prefabricated components made of light or gas concrete known. A disadvantage of these materials however, lies in their relatively high density which - as far as manual on-site handling availability should be preserved - considerable size restrictions result for the component. That in these components The hydraulic binder used also has one reduced resistance in the event of fire, since at increased temperatures with an expulsion at least  part of the water bound as hydrate and thus a corresponding loss in binding assets must become. The creation of walls from conventional Masonry is also time-consuming and especially wage-intensive.

DE 39 18 892 C2 discloses a fire-retardant partition intended for wall or ceiling openings for pipe or cable lines, which is formed from several layers and consists at least on the side facing the fire-risk area of an inorganic foam material. Other layers can, depending on the expected fire hazard from inorganic such. B. rock wool or organic materials such as. B. Best polyurethane foam. The inorganic foam material used is a material made from a solid mixture of SiO ₂ , Al ₂ O ₃ , filter ash, calcined bauxite and amorphous silica, a hardener made of alkali silicate solution that is reactive with this solid mixture, and a foaming agent suitable for splitting off oxygen, which is prepared by the customer and is molded into the area to be sealed off in the manner of a local foam, with hardening occurring after a few minutes. Such a material is also known from DE 37 44 210 A1.

The basic substance of the in DE-39 18 892 C2 and the DE-37 44 210 A1 described inorganic foam fabric is also, for example, from "Ceram. Eng. Sci. Proc.", July-Aug. 1988, pages 835-842 under the name "Geopo lymer ". This is a, by three-dimensional polymeric crosslinking alkali and silicon Comprehensive aluminate formed material that has a high has thermal stability at temperatures between  cures between 20 ° C and 120 ° C, can be shaped precisely and in has other properties of ceramic materials. However, the charak for ceramic materials does not apply Teristic, high energies due to the burning process tables and system engineering. find application can a geopolymer material hereafter u. a. as a construction material.

From DE-32 29 339 C2 and DE-33 03 409 C2 the use of the latter material in the context of a machine foundation is known. The practical processing of this material is based on the mixing of an aqueous alkali silicate solution, here a potassium silicate solution with a fine-grain solid mixture, which creates a molding compound that hardens in a mold at temperatures between 60 ° C and 100 ° C. A prerequisite for the suitability of the solid mixture within the molding composition is that it is reactive with the aqueous alkali silicate solution to form the stone-forming component. In this sense, suitable solid mixtures consist of metakaolin and fillers such as. B. corundum, heavy spar, zircon sand, mica, waste from bauxite melt, basalt flour, quartz, feldspar, etc. It can also be a mixture of solids with an oxide mixture in connection with the fillers mentioned, with oxide mixtures in mind at industrial high temperature Melting processes occur and consist, for example, of amorphous SiO ₂ and aluminum oxide.

The general use of these materials in the context of molding compositions is also known from DE-35 12 515 C2 and DE-35 12 516 C2. As a solid mixture, calcined bauxite is used, if necessary in combination with corundum and mullite from furnace filter dust or a glassy amorphous electrostatic filter ash, which consists essentially of SiO ₂ , Al ₂ O ₃ and Fe ₂ O ₃ . In any case, the reactivity with the aqueous alkali silicate solution for the stone-forming component is decisive for the suitability of the solid mixture.

The most important property of these geopolymer materials is that in almost every respect the most properties of ceramic materials can be achieved without that, however, the elaborate of the latter, by the manufacturing process requires manufacturing technology becomes.

DE-GM 88 00 623.9 is a multi-layer construction known element, which is made of brick, clinker, stoneware, Earthenware, etc., with the individual layers have different porosities and where about the porosity determines the function of the layer. That is made of ceramic materials The component is fired at 1200 ° C.

These known materials can be used for the production of Shaped bodies of any geometry are used, esp special for making more compact or cellular, too strand-shaped products. Size restrictions arise solely from the need to certain Not to exceed the transport weights of the molded articles, which result from manual transport or the handha exercise using a hoist.

For the production of walls it is known to use moldings assemble, but in the joint area or in the Joint materials are used that are not compatible with the Match the material of the molded body. This material  The inhomogeneity made a corresponding difference chemical, building physics and aging hold the molded body on the one hand and the joint material on the other hand. It is in this context pointed out the different resilience of ceramic materials on the one hand and at for example using hydraulic binders like cement made building materials on the other hand, what the latter generally require a protective coating fen. It should also be noted specific risks of binders based on water glass as well generally hydrated binders such as cement, plaster and the like against atmospheric influences.

DE-31 24 375 A1 is a cuboid structure stone known, consisting essentially of two components consists, namely a support element, which is similar is a conventional brick and consequently as brick porous stone, brick solid stone or Lime sandstone is formed and one on this support element glued mineral, for example Calcium silicate existing insulating plate. The isolation plate covers a full side of the support member and the building block thus formed has a global cuboid shaped basic shape. For gluing the insulation plate with the support element becomes a mineral adhesive used, but the material is not more specific is adorned. These building blocks are used to form a Walled in such a way that the insulating plates load-bearing sides oriented towards the outer wall of the building are, a masonry of these building blocks using application of thermal mortar to cold bridges in the mortar joints made of such bricks to avoid the wall element.  

Another component is from DE 35 25 768 A1 known, which is designed as a matrix component, the from a material of comparatively high density and Strength exists, the voids of this matrix building blocks with a lower density material, however higher thermal insulation capacity are filled. During the Concrete matrix material consists of its cavities with a foam-like material, open or closed filled with porous matter, which is expanded clay, Expanded mica, pumice stone granulate, gas concrete, foam glass gra nulate, granules based on polyurethanes, Polystyrenes, polyolefins, etc. can act. Such Building blocks can be put together to form a wall construction be placed in which these building blocks in vertical Stacking are arranged without bridging and thereby are held together by individual cavities Steep connection are bridged and so the composite of the building blocks. The outside and inside surfaces of the wall formed in this way can by a Binder which is reinforced with glass fibers or consists of a cement-like material, covered which holds the wall together and water it makes tight. Alternatively, you can use the wall construction Mortar as a binding agent between the individual building blocks be used. Characteristic of this, from DE 31 24 375 A1 and DE 35 25 768 A1 formed components or walls is that these as material inhomo are to be viewed.

It is the object of the invention, a generic Component with a view to being as universal as possible Usability in building construction, low manufacturing costs, a high level of fire safety, high resistance design and material homogeneity at which are both building technology and building physics  requirements are met. This is solved Task with a generic component by Features of the characterizing part of claim 1.

In this way there is almost a material homogeneous component, the joint material the radio tion of an adhesive that is practically the same material properties as the molded body as has such. The component can be part of a Wall or a wall element, a prefabricated block, a Building block of a general kind, a prefabricated chimney or a Part of the same or in the broadest sense also an installation lationselement such as. B. an installation shaft or be part of it. The homogeneity between joints material and molded body can be in material and in structurally, d. H. it is the joints material about a foaming process with one that Density of the molded body corresponding density poses. The moldings and / or the components, last re especially when they are parts of building components form, are industrially prefabricated. The usage a geopolymer material for the molded bodies as well the joint material essentially gives the component Chen properties of a ceramic material, wherein however, its elaborate processing is eliminated. in the The frame of the component only contains inorganic constituents share use so that this is not just as a whole is incombustible to look at but also in the event of a fire does not release any toxic gases. The Bauele ment can therefore be designed such that even high temperatures the mechanical bond of the same remains unchanged. The, from a geopolymer Existing molded articles are characterized by excellent resistance to Um influences of all kinds, especially towards each other  Moisture and are also very temperature sensitive constantly. The individual component has at least one Side surface covered with a layer, the material corresponds to the joint material. This leads to a further improvement in strength properties, such as B. penetration of the joints material in interface structures of the molded body. they leads to long-term durability, water and Fire resistance, thermal insulation and heat storage capacity as well as a high resistance to Alternating frost / thaw stresses. Both the molded body as well as the joint material can be used as part of the construction elements can be varied within wide limits, for example as a foam material or cell-ceramic material or as a compact other mineral work fabric, in any case by appropriate condition nation of the two material components Material homogeneity of the component is striving.

According to the features of claim 2, the Joint material and / or the material of the molded body can be used foamed. In some cases for example, the material of the molded body is foamed and that of the joint material is used without foam if this is with a view to increased strength speed is required.

The material used according to the features of claims 3 and 4 has proven to be very advantageous. In this part of the molded body, a material known per se based on a solid mixture of SiO ₂ , Al ₂ O ₃ , calcined bauxite, amorphous silica and filter ash, a hardener made of alkali silicate solution that is reactive with this solid mixture, and an oxygen-releasing foaming agent used. The static load-bearing capacity can be varied within wide limits by varying the density of this material. This material is essentially closed-pore, which results in a low water absorption capacity. Furthermore, this material also offers the advantage of bactericidal properties due to a strongly alkaline atmosphere (pH = 11). This foam material is foamed in a shape that can be achieved in any geometry, in particular thicknesses. Due to its porosity, there is a high level of thermal and acoustic insulation.

The one from the material of the molded body The same material formed joint material that forms flat-looking link between the individual Shaped bodies of the component, the joint material can be conditioned such that according to the characteristics of claim 5 at the same time at least the effect of a Barrier layer for liquid passage reached becomes. It becomes an otherwise due to the Porosity of the materials used possible migration prevented from moisture. As part of a Use of such building erected building special insulation measures are therefore not required against moisture. With an outer wall the components arranged so that the, from a molded body consisting of a geopolymer material the outside of which are located.

The made of another, inorganic porous material existing moldings can be according to the characteristics of claim 6 from lightweight concrete, gas concrete or the like Chen exist. These moldings are at Ver  purpose of the component in the context of a wall purpose moderately on the inside of a building and can be used here in the borderline case without an otherwise required Liche cover or protective layer are used. The Concrete moldings have a high porosity and therefore a correspondingly high moisture storage capacity. You can have one on the inside of walls Contribute to indoor air conditioning. Because concrete as Material is cheaper than the geopolymer material, can about the concrete portion of the component Manufacturing costs can be influenced favorably. Instead of However, lightweight concrete or gas concrete can also be more normal Concrete are used, which in particular the sta table load capacity of the component within wide limits is variable. It is a large group of materials concrete-like structure usable, e.g. B. also such Substances made using a carbonate Binder such. B. lime, limestone, marl or Substances using a hydrate forming Binders such as cement, hydraulic lime, etc. have been put. Finally, from mixing gene of the binders mentioned in connection with suitable th aggregates formed concrete-like materials to be used.

The other inorganic porous layer mentioned can but also according to the features of claim 7 Substances such as clay, clay or the like, but not in each case burned condition exist. This group of substances on the The base of clay minerals is characterized by a favorable formability and a high thermal insulation capacity. Another advantage of these fabrics is their wide range Distribution and almost universal availability and thus low production costs. Also comes into consideration Ceramics.  

By appropriate selection of the bulk density of the components can be easily conditioned so that there is sufficient static load-bearing capacity and these can also be used in the context of external walls are. Only in those cases where particularly there are high demands on strength, in particular this is the case when buildings formed from these components have to absorb tensile stresses, it can according to the features of claim 8 be advantageous in the Structure of the components, which in this case is expedient are partially formed as plates, areal Reinforcing elements. For example show the shape of perforated sheets, grids, steel mats or have fiberglass mats that either in the Structure of the molded body or the joint material inserted are bound.

The components according to the invention can, for example through a plate-like or cuboid base be characterized by its size and density is dimensioned such that an on-site manual hand Habung is just still possible, so that especially for Assembly no heavy lifting equipment is needed. The on components thus formed are for use for example as part of a building wall, one load bearing or non load bearing partition or the like are determined and are at their joints with joint materials of the type mentioned connected.

To prepare for a composite system of several components one side surface of the same with each other be coated with an inorganic layer, the substance Lich corresponds to the geopolymer material, which further  is foamed or not foamed. If necessary, can the number of pages covered with this material is, however, can be varied as desired, so that all surfaces can be covered in this sense nen. From this context it can already be seen that - after the joint material as a moisture barrier can work - a wall formed in this sense no further structural measures to prevent the Spreading moisture required. Also can the joint material in such a simple way be tioned that it forms a vapor barrier.

One can see a comparison in this sense formed building wall with conventional, by Stones with grouted butt joints formed the wall great advantage of a largely material Homogeneity.

Deviations between the behavior of a geopolymer Material and usual ceramic materials exist only in the case of exposure to hydrochloric acid, less for sulfuric acid, alkalis or other common gas shaped or liquid components of an industry the atmosphere.

The design of the component can ent speaking quite varied the features of claim 10 be active. Practical building components come into consideration any kind, such as B. stones, blocks, plates, support constructions, enclosing and partition walls, components technical building expansion such as sanitary blocks, Surface heating, e.g. B. underfloor heating, supports for Sanitary objects such as tubs, showers, installation blocks, Installation register, wet cells and elements of the same ben etc.

The invention is described below with reference to the Exemplary embodiments shown in the drawings are explained in more detail. It shows:

Figure 1 is a perspective view of a device according to the Invention.

FIG. 2 shows an end view of another embodiment of a component according to the invention in accordance with arrow II in FIG. 1.

1 in FIG. 1 denotes a prefabricated component in its entirety, which has a plate-like or cuboid shape globally and forms a component.

The component 1 is composed of two molded bodies, which in turn are plate-like, one molded body 2 made of a geopolymer material and one molded body 3 made of concrete or gas concrete. The molded bodies 2, 3 are connected to one another in a planar manner via an adhesive layer 4 and complement one another to form the cuboid shape of the component 1 .

The adhesive layer 4 consists of a non-foamed material corresponding to the material of the molded body 2 and, viewed in the direction of the arrow 5 , forms a barrier layer at least for the passage of water or moisture.

In the context of the component 1 , the two molded bodies 2 , 3 can each have the same mass fractions. Both moldings are adapted in terms of their density with a view to the desired static strength. Both materials, namely ceramic-like bond within the molded body 2 and hydraulic bond on the basis of cement or plaster in the molded body 3 have significant differences, which are taken into account in the practical use of the component 1 . For example, the molded body 2 is characterized by a high resistance to moisture, aggressive environmental media and the like, so that the molded body 2 is ideal for unprotected use in the context of the outer wall of buildings. The foam material used here has a comparatively small proportion of open pores, so that a high water absorption when used in the context of external walls is not to be expected. Precisely because of its high resistance to environmental influences, this molded body 2 can be used without the need for an outer cover layer.

A possible use of the component 1 is thus - as already mentioned - in the context of outer walls, the side 6 of the component forming the outside.

The barrier layer formed by the adhesive layer 4 is, for example, such that passage of liquid water in the direction of the arrow is suppressed, but not water vapor diffusion. However, it is also conceivable to condition the adhesive layer 4 in such a way that it simultaneously forms a vapor barrier layer. It is essential, however, that the adhesive layer 4 consists of an incombustible inorganic material in the same way as the shaped bodies 2 , 3 , so that the composite of the shaped bodies 2 , 3 is retained within the component 1 even when exposed to strong heat.

The concrete used in the molding 3 , for example gas concrete, is characterized by high capillarity and thus a large water storage capacity. This shaped body 3 with its side 7 is therefore preferably intended for use on the inside or inside of the building. Due to its capillarity, this material can make a favorable contribution to indoor air conditioning by absorbing and releasing moisture. This concrete-like material is not resistant to environmental influences to an extent corresponding to the foam material of the molded body 2 - however, this can be tolerated inside the room. In the case of use on the outside of the room, however, this material would have to be coated with protective layers in a manner known per se.

The concrete-like material used in the molded body 3 is relatively cheaper than the foamable material used in the molded body 2 and can be used as a whole in the context of the component 1 in accordance with the respective material content for the reduction in price.

The components 1 are expediently produced in such a planar extent that they just barely allow manual handling, ie possible on-site handling without the need for heavy lifting equipment. The production can be carried out, for example, in such a way that the moldings 2 , 3 are first produced in a conventional manner, which are then connected to one another using an adhesive layer 4 . From the combination of the so-called materials used in the moldings 2 , 3 , there is in particular the advantage that the existing thickness limitation in industrial prefabrication, for example of gas concrete plates, is now no longer applicable, in particular after comparable thickness limitations in the geopolymer material are completely eliminated.

There is also an advantage of this known material its easy workability, which with that of Wood is comparable.

The interconnection of the components 1 with one another in the context of a wall is expediently again formed using adhesive layers which correspond to the adhesive layer 4 in terms of material. In the context of such a wall, the fact that the building physical properties of the same can be regarded as largely homogeneous has a particularly advantageous effect. In particular, such as B. with conventional construction - inhomogeneities caused by mortar-based butt joints.

The inclusion of the components 1 in corresponding adhesive layers prevents simultaneous rise of moisture within the wall, so that the additional blocking measures otherwise required - as in conventional masonry - are not necessary. In this respect, the components 1 according to the invention also make a contribution to simplifying the construction.

The embodiment shown in Fig. 2 is characterized in that - seen in an end view - all sides of the component 1 'are coated with a gene 8 layer 8 , which consists of the substance of the molded body 2 , but is not foamed. This layer 8 can also extend over the end faces, so that the component 1 'shown is integrated on all sides in a coating that prevents moisture passage. In borderline cases, this coating can also be made impermeable.

Components 1 , 1 'can be used in almost any functional context in the context of buildings, such. B. in the context of statically load-bearing outer walls, statically non-load-bearing or only load-bearing Trennwan appendices, pipe installation shafts and other instalation facilities and in the context of chimneys. In the latter case, in particular the property of the molded body 2 , which is very resistant to environmental influences, can be used, in particular its very high temperature resistance.

The components 1 , 1 'are characterized by a high thermal and acoustic insulation according to the porosity, and safety aspects have also been taken into account in terms of preventive fire, after neither combustible nor smolderable substances are used in the context of the component and in the event of fire in particular also high and highest temperatures do not have a toxic effect the gases are released.

Claims (10)

1. Component ( 1 , 1 ') for use in building construction, best consisting of individual moldings ( 2 , 3 ), which are rich in the interstice with the interposition of an adhesive material acting as an adhesive, characterized in that

• - That at least part of the molded body ( 2 ) consists of a geopolymer material,
• - That the joint material is the material of the genann th part of the molded body ( 2 ) the same material,
• - That another part of the molded body ( 3 ) consists of another inorganic, porous material,
• - That the individual component ( 1 , 1 ') is formed by a plate-like or cuboid base body, the at least one side surface of which is coated with a layer ( 8 ) which corresponds in terms of material to the joint material,
• - That the geopolymer molded body ( 2 ) have a density of 0.1 gcm ^-3 to 1.0 gcm ^-3 and
• - That the joint material has a density of 0.2 gcm ^-3 to 2.0 gcm ^-3 , preferably more than 1.0 gcm- ³ .

2. Component ( 1 , 1 ') according to claim 1, characterized in that the joint material and / or the material of the molded body ( 2 ) is foamed. 3. Component ( 1 , 1 ') according to claim 1 or 2, characterized in that the geopolymer material is a known material from a solid mixture consisting of SiO ₂ , Al ₂ O ₃ , filter ash, calcined bauxite and amorphous silica and an alkali silicate solution reactive with the solid mixture. 4. Component ( 1 , 1 ') according to claim 3, characterized in that the geopolymer material is known per se, comprises oxygen-releasing foaming agents. 5. Component ( 1 , 1 ') according to one of claims 1 to 4, characterized in that the joint material is conditioned to the extent that it forms at least one barrier layer for liquid. 6. The component ( 1 , 1 ') according to any one of claims 1 to 5, characterized in that said other part of the shaped body ( 3 ) made of a concrete-like material produced using a carbonate- or hydrate-forming binder, in particular a lightweight concrete, gas concrete or the like. 7. Component ( 1 , 1 ') according to any one of the preceding claims 1 to 5, characterized in that said other part of the shaped body ( 3 ) consists of ceramic, clay, clay or the like. 8. The component ( 1 , 1 ') according to any one of the preceding claims 1 to 7, characterized by area reinforcements in the form of perforated plates, grids, mats or the like, which extend within the molded body ( 2,3 ) or the joint material. 9. The component ( 1 , 1 ') according to one of the preceding claims 1 to 8, characterized in that the joint material corresponds structurally to the geopolymer material of the shaped body ( 2 ). 10. The component ( 1 , 1 ') according to one of the preceding claims 1 to 9, characterized in that it is designed as a finished installation device, prefabricated chimney, wall element or as part of the same.