DE7837214U1 - Aerated concrete component - Google Patents

Description

YTOKG AG, Volkartstr. 83, 8000 Munich 19

Aerated concrete construction part ^^^ y

The invention relates to an aerated concrete component which has glass fibers.

Aerated concrete components are - if they have high tensile forces should be exposed - reinforced. Usually the reinforcement is done with steel mesh, among other things. The steel mats are in the core of the aerated concrete component. They are used prior to pouring the component into the mold introduced so that they are in the aerated concrete block after the autoclave has hardened. This way you can only relatively thick and heavy components are produced.

It is also used to increase the strength of heat-insulating, non-combustible wall elements known, between two wall panels plate strips trapezoidal cross-section and between to arrange these and the wall panels zigzag-shaped webs made of a cement mortar layer. Each blackboard can be made of a glass fiber reinforced cement mortar layer containing light mineral fillers be educated. Likewise, the spaces between the plate strips can be made from a Cement mortar layer, which have the same

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has components like the mortar layer on the wall panels. Aerated concrete is used as the strip material used.

In addition to the mandatory mineral light fillers with glass fibers, the cement mortar should be used be offset so that the mortar develops a higher tensile strength and thus the desired strength of the Wanaelement can guarantee. The fiberglass are - like all other ingredients - mixed with the mortar when it is mixed, so that the glass fibers containing mortar as fresh mortar applied in layers with nozzles to the substrates provided will. The strength of the wall element depends on the strength of the hardened mortar. The strength of the mortar, in turn, is based on the adhesive force between the individual fiber fragments and the hardened cement stone. Because of the alkaline environment in the hardened cement stone, alkali-resistant Glass fibers are used. However, such fibers develop only relatively in a cement matrix low adhesive forces, so that in particular the tensile strength of the mortar does not increase significantly will. Little is known about alkali resistance under long-term conditions.

The object of the invention is to create a reinforced aerated concrete component that is particularly suitable as a relative thin member can be made and has high tensile strength.

Accordingly, the subject matter of the invention is a particularly plate-shaped aerated concrete component which has glass fibers and is characterized in that it is superficially reinforced with at least one * glass fiber mat.

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The use of fiberglass mesh to reinforce Aerated concrete components is by no means obvious, because the expert knows that a glass fiber with the aerated concrete component cannot easily be connected and, in addition, the lack of corrosion resistance of a glass fiber prohibits their use in the alkaline environment of aerated concrete. According to the invention, the

I tion of an aerated concrete component, however, in such a way that

I.
/ I none of the known problems have a detrimental effect

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'- According to a particular embodiment of the invention

I the honoring glass fiber mat lies on the surface

I the aerated concrete component and protrudes with the component

; 15 a hardened mortar glue, especially cement paste,

I in connection, whereby the glass fiber mat essentially ensures the strength of the aerated concrete component.

I perform. In the above-described known wall

^v 'element, on the other hand, is only the strength

'f, 20 taken over from the cement mortar layer,

I stiffness relatively insignificant due to the presence

I the disjointed criss-cross in the mortar

I shared, usually increased very short glass fibers

1 will. According to the invention essentially carries

I 25 fiberglass mat the strength of the aerated concrete component, I where the mortar has a sufficiently high elasticity

I module to allow relative movements between the gas

^{5 to} catch the concrete core of the component and the glass fiber mat and to enable force transmissions without cracking by anchoring both with the glass fiber mat and with the aerated concrete surface.

It has surprisingly been found that the tensile or flexural strength of the gas-35 according to the invention concrete component is higher than the adhesive force of a

Glass fiber with the cement glue suggests. With the |

The component according to the invention is therefore not this verse

binding type is of crucial importance, but the ί

6 mesh or grid-like mechanical anchoring of the Ϊ

Glasfasermatjte in the hardened cement paste. Due to the fact that ϊ the fresh cement paste the 5

f-Iattenlöcher in the production of the aerated concrete construction ξ

partially penetrated and then hardened, tooth /

or pin-ax mechanical anchoring created, the adhesive force arising from the physico-chemical between the fiber and hardened cement paste.

It is particularly advantageous to use a glass fiber fabric, which forms pronounced knot-like crosspieces at the points of contact between warp and weft. In this case, the nodes, which are stored in depressions of the hardened cement paste, support the tooth-like mechanical anchoring of the fiberglass mat.

In contrast to the conventional reinforcement of aerated concrete with steel mats, which are housed in the core of the aerated concrete component the reinforcement according to the invention can be arranged superficially. This requires statically the known advantages that result when the element that absorbs the tensile forces should, is arranged in the area of the highest tensile stresses. This also enables very thin ones and to make large-format aerated concrete slabs at least safe to handle; because especially thin aerated concrete slabs are very difficult to transport, if at all, due to the high risk of breakage and handle. |

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It is expedient to choose the thickness of the Zeiners ti including only so that the glass fiber mat is just embedded in it and rests directly on the surface of the aerated concrete. In this context, it has surprisingly been shown that not only glass fiber mats made of particularly alkali-resistant glass fibers can be used, but in particular also mats made of glass fibers with normal alkali resistance, e.g. B. E and / or F glass fibers exist. The latter fibers even surprisingly achieve higher strengths. Surprisingly, the alkaline environment in conventional components, which occurs again and again after a long period of time, does not have a damaging effect on the component according to the invention. Apparently the responsible for this alkaline environment Ca (OH) _p in the very thin mortar layer is neutralized after a short time by conversion to CaCO ₀ , so that egg
can exert on the glass fibers.

neutralized in CaCO ₀ so that it no longer has any influence

According to the invention, it is even possible to use lattice-shaped glass fiber mats made of a plastic consists of plain coated fiberglass bundles, the bundles being woven into a coarse-meshed fabric are. In this case, the cement paste is only in contact with the outer individual fibers of the bundle and could only attack them. A chemical attack is also avoided in that each individual fiber is coated with a plastic size. In turn, the plain is usually responsible for a low adhesion between cement glue and fiberglass bundle, so that the use such a fiber optic bundle is not immediately obvious. According to the invention, the required anchoring between the fiberglass mat and cement glue essentially through the knots and openings of the fabric

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guaranteed.

With the invention it is thus possible, in particular, to produce thin aerated concrete components with external reinforcement to create, whereby the reinforcement is connected to the aerated concrete via a hardened mortar and the mortar is anchored to the aerated concrete surface is.

Mats are preferably used as glass fiber mats

2 applies with a weight of 100 to 150 g / m and

a tensile strength (warp and weft) of 200 to 400 N / mm.

The mats are used in the manufacture of the invention The aerated concrete component is pressed into a layer of fresh mortar that was previously applied to an aerated concrete surface has been. The thickness of the mortar layer depends on the type of fiberglass mat used and can be determined empirically. The composition of the mortar should be chosen so that the free CaO as quickly as possible in CaCO.-, converted can be. It is advantageous for the

wrote fiberglass mats mortar layer thicknesses of 1.0 to 4.0 mm, in particular from 2.0 to 2.5 mm, to be selected.

Preferably, mortars are used, the methyl cellulose and have the following composition: 30

40 to 70% by weight of sand (grain size 0 to 0.5 mm) 25 to 60% by weight of binder, preferably

cement

3 to 10 wt -.% Hydrated lime On 3 to 0.6 parts by weight 96 Methyleellulose

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Instead of or in addition to methyl cellulose preferably a 50:50 synthetic latex dispersion, especially a styrene-butadiene-latex dispersion, used, which is mixed with 1 in 5 to 1 in 10 with water. The mortar is preferably made with a Water solids factor of 0.3 plotted. The composition the mortar is chosen in all cases so that the mortar applied in a thin layer from Aerated concrete does not have the water required for hardening

IC is withdrawn, which is the case with conventional mortars due to the high The pumping speed of aerated concrete occurs especially when mortar is applied in very thin layers. It is also important that a bonding agent is used between the mortar and aerated concrete, which ensures that that the hardened mortar is firmly anchored in the aerated concrete surface. The adhesion promoter can be used as thin layer between the mortar and dsm aerated concrete. But you can also use the fresh mortar Mix in the adhesion promoter homogeneously. As a bonding agent synthetic latex is preferably used, as described in more detail above. It has turned out to be surprising Shown that the latex component of the cement

apparently the alkali resistance of glass fibers

improved. It is conceivable that this substance is %

preferably arranged on the glass fiber surface and prevents contact with the alkaline solutions of the cement paste.

The invention is illustrated by way of example with the aid of the drawing explained in more detail. Show it:

Fig. 1 schematically a single reinforced aerated concrete component,

Fig. 2 schematically a reinforced aerated concrete component, consisting of several together

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combined aerated concrete slabs.

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The aerated concrete component according to the invention can be any flat Have a shape that can be produced from aerated concrete. The example shown is for simplicity half cuboid plates 1 has been chosen. These are preferably 2 to about 7.5 cm thick. Eie Panels preferably have a hardened mortar layer 2 on both sides, in which a conventional glass fiber fabric 3 is pressed in or embedded.

The mortar layer is expediently 1 to 4, preferably 2 to 2.5 mm, thick. The aerated concrete slab 1 preferably has a bulk density of 0.3 to 0.5

3
kg / dm.

In the example shown, the weft and warp of the glass fiber fabric run parallel to the edges of the panels 1. However, especially in the embodiment according to FIG. 2, it may be useful to use warp and weft to be arranged at an angle to the panel edges- Furthermore, to increase the bond it can be advantageous if between a joint 4 filled with mortar (FIG. 2) is provided on the side surfaces of the panels, the joint mortar may have the same composition as the mortar layers 2.

To produce the aerated concrete component according to the invention, the autoclave-hardened aerated concrete slab is or A fresh mortar layer of the desired thickness is applied on both sides and immediately afterwards the Glass fiber jatten fabric pressed into the mortar layer. Subsequently, the coated plate is preferably stored for seven days to allow the mortar to harden Air. It is advantageous, however, to cure in one

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Heat chamber with high humidity and high CO _? -Content, so that the hardening time can be shortened and the carbonation of the free CaO in the mortar takes place quickly. According to a particular embodiment of the invention, curing takes place in the autoclave at elevated temperature and pressure, which results in particularly good anchoring of the glass fibers with the mortar. Finally, it should be pointed out that the use of a latex dispersion in the mortar has unexpectedly shown that the bond or anchoring between the hardened cement paste and the glass fiber is strengthened.

The glass fiber mat reinforced aerated concrete component according to the invention is very easy to handle and relatively unbreakable. It is also very easy to nail and glue and especially a good plaster base because of its relatively rough surface. Of course it is also possible to use the invention for the repair of cracks in aerated concrete components. In this case, the fresh mortar layer is preferably applied to the gas concrete part that has already been installed and then pressed in the fiberglass mat.

Claims (6)

DR SOLF & ZAPF »j ·"; ■ · · "; "" PATENT LAWYERS: DR.-ING. DIPL.-ING. A. SOLF DIPL.-ING. CHR. 2APF Wall 27/29 5600 Wuppertal 1 Postfach 13O219 I / p / 1131 G 'YTONG AG, Volkartstr. 83, 8000 Munich 19 Protection claims: 1. Aerated concrete component comprising glass fibers, characterized in that it superficially with at least one glass fiber mat is reinforced. 2. Aerated concrete component according to claim 1, characterized in that the glass fiber mat is arranged on the air surface of an aerated concrete part and is connected to the aerated concrete part via a hardened layer of mortar. 3. aerated concrete component according to claim 2, characterized ze ichnet that the mortar layer consists of a cement mortar. 4. Aerated concrete component according to one or more of the claims 1 to 3, characterized in that the glass fiber mat is made of glass fiber fabric consists. 5. Aerated concrete component according to one or more of the claims 1 to 4, by which geken η marks, that the fiberglass mat is embedded in the mortar layer and the surface the aerated concrete part contacted. YTONG AG - 2 - \ i 6. aerated concrete component according to one or more of the Proverbs 1 to 5, characterized in that the glass fiber mat is physico-chemical and is mechanically anchored in the mortar layer. 7. aerated concrete component according to one or more of the claims 1 to 6, characterized in that the mortar layer 1 Ma 4, preferably 2 to 2.5 mm thick. 8. Aerated concrete component according to one or more of the claims 1 to 7, characterized in that the aerated concrete part consists of several Plates (1) from 2 to 7.5 cm thick, which have a bulk density of 0.3 to 0.5 kg / dm. 9. aerated concrete component according to one or more of claims 1 to 8, characterized draws that the fiberglass mat a Glass fiber fabric (3), which is preferably made of glass fiber bundles coated with a plastic size consists. 10. aerated concrete component according to claim 9, characterized marked that weft and chain of the glass fiber fabric (3) run parallel to the edges of the panels (l).!. 11. aerated concrete component according to claim 10, dad u r c h I mark the fact that between the plate side surfaces a joint (4) filled with mortar is arranged. YTONG AG 12. Aerated concrete component according to one or more of claims 1 to 11, characterized in that that the mortar has the following composition: 40 to 70 wt .-% of sand (grain size 0 to 0.5 mm) 28 to 70 wt .-% of binder (cement and lime) 0.3 to 0.6 wt -.% Methyl cellulose from 0.3 to 0, 6% by weight 50 to 50 styrene butadiene latex Disoersion.