DE3824598A1 - INSERT FOR FIRE PROTECTION DOORS WITH PEBBLE SOL - Google Patents

Abstract

A fire-resisting wall element (1) reducing heat transition and with at least two insulating layers (2, 2a) made from bound mineral wool contains a layer (3) arranged between the insulating layers (2, 2a) which is produced from a mixture of a dehydrating hydroxide and an inorganic binder such as water glass or silica sol. The layer (3) increases the fire resistance of the wall element (1) which is therefore particularly suited as an insert for a fire-check door. <IMAGE>

Description

The invention relates to a fire-resistant, the Wall element reducing heat transfer, in particular as an insert for a fire-retardant door, according to the waiter Concept of claim 1.

To achieve a high fire resistance class at wall-like building elements, thermal insulation is sought to combine with fire protection zones, their warmth absorption capacity is significantly increased in that Temperature rise in case of fire endothermic chemical Reactions or phase changes take place. As is well known the fire resistance is determined according to the Duration at which a certain temperature rise on one side of the wall element the other side the wall element below a certain limit temperature, e.g. B. 180 ° C remains. The service life of the wall element up to to reach this limit temperature on the cold  Page in minutes gives the fire resistance class where in accordance with DIN 4102, Part 5 z. B. the classification in the Fire resistance class F 30 a 30-minute service life F 90 means a 90-minute standstill etc. It lies on hand that only through thermal insulation measures a limited delay in temperature rise too can be achieved on the cold side, and this relatively large wall thicknesses are required. About it there are also thermal insulation materials with a correspondingly high level Thermal resistance on the one hand and under the wall sufficient temperature resistance not available, with the exception of asbestos, that due to its harmful effects should not be used. Mineral wool, itself Stone wool sinters under the high fire temperatures starting from the hot side and thus pays off low wall thickness on the hot side relatively quickly their effectiveness as thermal insulation material, so that rela tiv large wall thicknesses are required; continues to point Mineral wool has a relatively low heat capacity on and can therefore the temperature rise on the cold side due to its own heat absorption with small wall thicknesses only delay insignificantly.

As a material for a layer created by storage latent heat due to phase change the temperature delay on the cold side is particularly special plaster in practical use. The right relatively high enthalpy when the crystal water is split off used, which takes place from approx. 50 ° C. However, plaster can be considered a layer with the dimensions required in practice only handled in the form of so-called gypsum plasterboard with a layer of plaster on both sides with cardboard is covered. The cardboard lamination naturally increases the fire load and promotes the formation of flammable  Smoldering and decomposition gases.

There has been no shortage of attempts, such latent heat-absorbing fire protection zones from others Manufacture fabrics that have no lamination from orga niche fabrics or the like.

For this purpose from DE-OS 30 23 632 sodium metasilicate has become known, a substance that at about 48 ° C below Heat absorption in your own crystal water melts and is stable in the molten state. Here there is however, the problem is that the melt is relatively low viscosity even at the lowest temperatures is formed and of course has a tendency to develop in lower area of the available space to collect. This just becomes the hot top area entirely of the material of the layered fire protection zone exposed, so that there the temperature at the cold side rises practically by leaps and bounds. After Teaching of DE-OS 30 23 632 is the sodium metasilicate to avoid draining too quickly into one open-pored support structure made of a wettable material, for example granulated mineral wool, embedded will. According to a similar teaching of DE-OS 30 22 945 If a substance is also to be introduced, the the melt binds and with this a doughy or forms solid mass. However, it has been shown that with such measures, the outflow of the melt somewhat delayed, but not ver can be prevented. In addition, the low one is annoying Melting point of sodium metasilicate of approx. 50 ° C, the achieved even without fire under unfavorable influences can be, so that over time even without Outbreak of fire repeatedly melt and in the bo can accumulate the area, so that in fact  Fire resistance the fire resistance in the upper Be range of the wall element can already be greatly reduced can.

DE-OS 35 10 935 is a generic fire resistant, heat transfer reducing Wall element known. In the known wall element two insulation layers made of bound mineral wool with min at least one fire protection zone made of granules made of Al potash or alkaline earth carbonate combined, the Gra nulate by an inorganic binder, e.g. B. Magne siabinder, is bound. This well-known wall element does provide sufficient resistance to a fire opposite; because the material of the fire protection zone is made of Alkali or alkaline earth carbonate in the form of granules stands, the fire protection zone is relatively wide, too leads to a relatively large thickness of the wall element. In addition, the known wall element is very heavy.

In contrast, the invention is based on the object a wall element in the preamble of claim 1 given genus, which in combination with mineral fiber insulation layers a high fire resistance class like F 90 according to DIN 4102, part 5 with compared to State of the art reduced thickness and reduced Can easily reach weight.

This problem is solved by the character nenden features of claim 1.

By using only inorganic substances, it is first of all ensured that there is no organic substance that could produce flammable and / or toxic gases in the event of a fire. Aluminum hydroxide, Al (OH) ₃ (hydrargillite) changes to AlO (OH) (boehmite) when heated to approx. 150 ° C, which at approx. 400 ° C changes to gamma-aluminum oxide with water elimination:

2 Al (OH) ₃ → 2 AlO (OH) → Al₂O₃

Instead of aluminum hydroxide, other hydroxides, e.g. B. Magnesium hydroxide Mg (OH) ₂ , calcium hydroxide Ca (OH) ₂ , iron hydroxide Fe (OH) ₃ or FeO (OH) can be used, which is converted into the corresponding oxides MgO, CaO, Fe ₂ O ₃ etc. with elimination of water will. The conversion of the hydroxides into the corresponding oxides is an endothermic reaction, whereby heat is absorbed. Furthermore, water is released in a heat-consuming endothermic reaction, which escapes in the form of water vapor.

Silica sol is a colloidal solution of amorphous silicon dioxide in water, to which small amounts of alkali are added to stabilize it in technical qualities. Commercial silica sols which occur as anionic or as cationic silica sols contain, for example, 15 to 45% by weight of solids, calculated as SiO ₂ . The ver binding layer between the insulating layers of bound mineral wool of the wall element according to the invention is preferably added as a silica sol, an anionic silica sol with a solids content of 30 to 45 wt .-%, in particular 40 wt .-%. In the mixture used according to the invention, silica sol serves as a binder and also splits off water during the transition to the crosslinked gel state and during aging and during heating, with the formation of silicon dioxide according to the following equation:

Si (OH) ₄ → SiO (OH) ₂ → SiO₂.

Aluminum hydroxide in the form of the commercial Martinal in inert in the pH range between 3.5 and 10.5 and insoluble in acids and alkalis. Therefore the mixture of Al (OH) ₃ (pH about 9 l) and silica sol (pH about 9 to 10) is stable.

Instead of silica sol, however, a water glass, for example potassium or sodium water glass, can be used in aqueous solution as a component of the mixture. Such solutions are strongly basic so that they slowly attack aluminum hydroxide. If this reaction with water glass is disruptive, Mg (OH) ₂ , Ca (OH) ₂ , Fe (OH) ₃ or FeO (OH) or another hydroxide instead of aluminum hydroxide can be used together with water glass as the water-releasing hydroxide.

However, any water-releasing hydroxide, for example Mg (OH) ₂ , Ca (OH) ₂ , Fe (OH) ₃ or FeO (OH), can also be used together with silica sol.

To produce the wall element according to the invention a mass of a suitable water-releasing Hydroxide, e.g. B. aluminum hydroxide, and a silica sol processed into a plastic mass that on a Apply an even layer on one side of an insulation layer will.

70 to 95% by weight of aluminum hydroxide and 30 to 5% by weight of silica sol, calculated as SiO ₂ , in particular 80 to 90% by weight of aluminum hydroxide and 20 to 10% by weight of silica sol, for example 85% by weight, are preferably used. Aluminum hydroxide and 15 wt .-% silica sol used. It is also possible to use clay or alumina in the form of a powder or an aqueous slurry instead of part of the aluminum hydroxide or in addition to aluminum hydroxide.

A second layer of insulation is applied to the still damp layer applied and by applying light pressure with the layer the plastic mass evenly connected. By Transition of the silica sol to the cross-linked gel state the two insulation layers become irreversible with each other glued and connected.

For ordinary applications, the so manufactured Wall element sufficient fire resistance. At an increased requirement for fire resistance ability to add one or more insulation layers same way with the wall element thus produced can be glued sandwich-like. The solidification of the Kieselsols takes place in a period of 2 to 8 hours the. It can e.g. B. by heating or microwaves drying can be shortened considerably. The water from the damp mixture of hydroxide and a water glass or Silica sol is distributed in the neighboring insulation layers and can evaporate over time. The firmness however, the connecting layer is not one Complete removal of water depends on it especially on the transition of water glass or silica sol based on the cross-linked gel state.

To increase the fire resistance values, the thickest possible insulation layers made from bound mineral wool can be used. However, the thickness of the insulation layers is limited by the prescribed maximum thickness of fire protection doors and by the high weight of fire protection doors with very thick insulation layers. In practice, panels with a thickness of 20 to 40 mm, in particular 30 mm and a bulk density of 140 to 280 kg / m ² , in particular 200 kg / m ^2, have proven to be good insulation layers. The connecting layer of inorganic material is applied in such a thickness that after pressing it has a thickness of 2 to 5 mm, in particular 3 mm or a basis weight of 5 to 10 kg / m ² , in particular 7 to 8 kg / m ² owns. With such a symmetrical or approximately symmetrical wall element, excellent fire resistance values can be achieved. The reason for this is probably that in this case the outer insulation layer made of mineral wool facing the respective fire firstly insulates the connecting layer of inorganic material, which also serves as a fire protection zone, and protects it from direct flame access, so that the latter only becomes fully flammable later is affected. In this case, the second insulation layer made of mineral wool remains, which is arranged on the cold side in order to effect the required insulation on the cold side. This insulation layer is protected by the connecting layer acting as a fire protection zone and can therefore fully develop its insulation effect over a long period of time. Further details, features and advantages of the present invention result from the following description of an embodiment with reference to the drawing.

The figure shows a view of the invention Wall element.

The wall element 1 consists of two insulation layers 2 , 2 a of mineral wool, which are connected by a connecting layer 3 , made of a mixture of a water-releasing hydroxide and a silica sol. The connecting layer also serves as a fire protection layer, since in the event of a fire it converts to aluminum oxide or silicon dioxide when heated and not only releases water vapor during this endothermic conversion, but also consumes a large amount of energy. Furthermore, the connecting layer 3 forms a tight coating for the insulation layer 2 or 2 a after its heating, which faces away from the fire. While the insulation layer facing the fire sinters together relatively quickly under the action of heat, the connecting layer 3 delays the sintering together of the insulation layer 2 a or 2 facing away from the fire, as a result of which a rapid increase in temperature on the cold side can be avoided.

The wall element according to the invention serves in particular as an insert for a fire-retardant door. For the production of such a door, the wall element 1 can be prefabricated in the form of a composite panel between the sheet steel shells of a fire door. On the other hand, it is possible to insert an insulation layer in a sheet steel shell of the fire protection door, to apply the connecting layer from the mixture of a water-releasing hydroxide and a silica sol to the insulation layer and then to fit the second insulation layer onto the connecting layer in the steel sheet shell for the fire protection door , after which the two layers of insulation are dried and cured.

A particularly preferred process is used the dehydrating hydroxide in solid form or in Form of a plastic aqueous slurry of silica sol or dissolved water glass, mixes the two be components z. B. in a screw conveyor and brings that obtained homogeneous mixture on one of the two insulation layers in an even layer. Then will the 2nd insulation layer is applied to the connecting layer and pressed.

This embodiment of the method according to the invention is particularly economical because the process is continuous be carried out nuously or semi-continuously  can and the mixture according to their consumption for Production of the connecting layer can be produced can.

Claims (9)

1. Fire-resistant, heat-reducing wall element, in particular as an insert for a fire-retardant door, with at least 2 insulation layers made of bound mineral wool, between which there is a layer of inorganic material connecting these insulation layers, characterized in that the connecting layer consists of a Mixture is made of a water-releasing hydroxide and a water glass or silica sol. 2. Wall element according to claim 1, characterized in that the water-releasing hydroxide is aluminum hydroxide is. 3. Wall element according to claim 2, characterized in that the connecting layer made of a mixture of 70 to 95 wt .-% aluminum hydroxide, calculated as Al (OH) ₃ and 30 to 5 wt .-% silica sol, calculated as SiO ₂ is. 4. Wall element according to claim 3, characterized net that the mixture of about 85 parts by weight Aluminum hydroxide and about 15 parts by weight of Kie selsol exists. 5. Wall element according to one of claims 2 to 4, there characterized in that the mixture instead of egg part of the dehydrating hydroxide or too in addition to the water-releasing hydroxide Contains clay. 6. Wall element according to one of claims 1 to 5, there characterized in that the connecting layer has a smaller thickness than any insulation layer. 7. Wall element according to claim 6, characterized in that the connecting layer 1 to 5 mm, in particular Is 3 mm thick. 8. Wall element according to one of claims 1 to 7, there characterized in that the mineral wool stone is wool. 9. Process for producing a fire resistance changes that reduce heat transfer tes according to any one of claims 1 to 8, characterized characterized in that one in a continuous or semi-continuous process from the water cleaving hydroxide in solid form or in the form of egg Plastic aqueous slurry of silica sol or added dissolved water glass, both components  mixed, the mixture obtained on one of the 2nd Applying insulation layers in an even layer and the 2. Apply the insulation layer to the layer and press it on.