DE7032003U - NON-COMBUSTIBLE STRUCTURE, IN PARTICULAR PANEL. - Google Patents

Description

Non-combustible structure, especially a plate

The innovation concerns a non-combustible structure, especially a plate, im

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Gross density range from approx. 400 - 1000 kg / m

There are known processes for the production of incombustible panels and moldings, which mostly come from asbestos or plaster of paris. During the plaster itself over has sufficient binding power, the asbestos panels are bound with cement or other mineral binders. To increase strength Glass fibers are sometimes added to the plasterboard.

The known plates and moldings made of asbestos and plaster of paris have the disadvantage that they have high specific weights that make manipulation with these materials very difficult. For this reason it is also difficult possible to produce thick panels, i.e. those with a thickness of more than 25 mm. The surface treatment by veneering or gluing with laminate

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In the case of the well-known incombustible panels made of asbestos or gypsum, the following substances are prepared: also considerable difficulty, as there is only an inadequate bond between the carrier material and the coating.

In addition to the above-mentioned plates and moldings made of asbestos and plaster of paris, one has already tried the same materials from native Giimmer mareriaiien known as vermiculite. The bloated Mica material is often incorporated into plaster of paris in order to achieve the specific To reduce the weight of the plasterboard. At the same time, the strength of the plasterboard is also reduced. Even with the well-known records that consist almost exclusively of vermiculite with a little binding agent only low strengths can be achieved, so that these panels have so far only been used as cladding panels. With all known plates and moldings from expanded mica material it has so far not been possible to achieve a binding of the mica particles, both in the fire and under Is resistant to moisture.

The DBGM 1 946 275 already shows a building board made of expanded minerals, which are bound with phosphoric acid or acidic phosphoric acid salts. Further the building board contains additions of basic oxides or minerals. Vermiculite, perlite or expanded clay are used as expanded minerals. Monoaluminum phosphate is suggested as a binder. Panels of this type have, on the one hand, insufficient strength and, on the other hand, show Disadvantages of combined use.

It is the task of the innovation to remedy the shortcomings of the known non-combustible Eliminate structures and solve the problems identified. According to renewal this is achieved by a structure of the type described at the beginning

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achieved, which consists of three layers of expanded iron aluminum silicate, with a mineral fiber fabric impregnated with binding agents being arranged between the middle layer and the outer layers. Here, all Schich ^f "n with inorganic and / or organic binders connected. In a particular embodiment, the structure has an additional planking that essentially increases the flexural strength, e.g. B. made of veneers, Kunstfoarzimprägnierten papers, foils and the like. On.

Special advantages are achieved when a combination of binders is used inorganic and organic components is used. The inorganic part consists preferably of phosphate and phosphoric acid, ζ. B. monoaluminophosphate and orthophosphoric acid, while the organic portion is a formaldehyde condensation resin, e.g. B. urea, melamine or phenol-formaldehyde resin is. While the phosphoric acid and the phosphates guarantee the cohesion of the building structure when exposed to heat, fire, etc. "/ the organic binder ensures sufficient moisture resistance.

The structures after the innovation have a relatively low weight

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from about 400 to 800 kg / m. Nevertheless, they can withstand stress

2 with a flexural strength of about 80 to 160 kp / cm.

In a further embodiment, there are the middle layer and the outer layers from a mixture of expanded iron aluminum silicate and expanded calcium silicate.

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-A-

The starting materials for production can also be used with particular advantage stretch the non-combustible structure through fillers, with clay minerals or solidifying materials such as mineral as filler Fibers.

The structure of the non-combustible structure according to the innovation is illustrated in the attached sectional view. The structure has a three-layer structure, namely the outer layers 1 and the middle layer 2. In order to achieve good surface properties, is

preferably a planking 3, for example as a veneer, synthetic resin impregnated Paper or the like trained, available. Between the middle layer 2 and the outer layers 1 there is in each case a synthetic resin impregnated one Mineral fiber fabric 4, which is primarily intended to increase the flexural strength of the plate.

The plates and bodies are generally manufactured in such a way that that the expanded mica material is first sprayed in a mixer with a mixture of phosphoric acid and aluminum phosphate, the amount applied being between 5 and 40% of the weight of the mica ~ may vary. Subsequently, Im the same or a subordinate

Mixer the organic resin in powder form or as a solution on top of the

Abandoned mica particles, the amount between 1 and 10% resin can vary based on the mica weight.

The mixture provided with binding agent is then formed into a molding endlessly or in tabular form or in a so-called extrusion press, the mineral fiber fabric at the same time in the molding embedded between the middle and top layers.

The finished molding is then pressed in a heated press and

hardened. The press tempera door is usually 150 C to 350 C,

A ^ r trial print 5 bi? 25 ko / cm and a price time 5 to 20 minutes.

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Claims (7)

■ protection claims; Non-combustible structure, especially Piarfe, in the Rondichfebe- 3
ranging from 400-1C30 kg / m, characterized in that the plate consists of three layers of expanded iron aluminum silicate and a mineral fiber fabric (4) impregnated with binding agents is arranged between the middle layer (2) and the outer layers (1), whereby all Layers are connected with inorganic and / or organic binders. 2. Structure according to claim 1, characterized by an additional that Strength-increasing planking (3), e.g. made of veneer, resin-impregnated Papers, foils and the like. 3. Structure according to claim 1, characterized in that the inorganic Part of the binder combination consists of phosphate and phosphoric acid ... e.g. monoaluminium phosphate and orthophosphoric acid, during the organic content a formaldehyde condensation resin, e.g. B. urea, melamine or phenol formaldehyde resin. 4. Structure according to claim 1 and 2, characterized in that the Middle layer (2) and the outer layers (1) made of a mixture of expanded iron aluminum silicate and expanded calcium silicate exist. 7032003 17.1Z 70 5. Structure according to claim 1 to 4, characterized in that the expanded iron aluminum silicate fillers, such as clay minerals, Anhydrite, magnesite or solidifying substances, such as mineral fibers, are added. 6. Structure according to claim 1 to 5, characterized in that this in its middle layer (2) a coarser structure than in the top layer sn (1) has, 7. Structure according to claim 1 to 6, characterized in that the individual layers (1, 2) have different Qindemitfelgehait.