DE20305238U1 - Fire protection glazing and bracket for a plate-shaped component - Google Patents

Description

Fire-resistant glazing and bracket for a plate-shaped building element

The invention relates to a fire-resistant glazing and holder for a plate-shaped building element with a multi-layer glass pane element and a fire protection pane glued to this glass pane element on the fire side, wherein the fire protection pane is set back along the edge relative to the glass pane element.

Fire-resistant glazing of this type is known from EP O 528 781 B1. This discloses fire-resistant glazing with a glass pane element sitting in a holding frame with a prestressed silicate glass pane glued on the fire side, which ends at a distance in front of the holding frame. The prestressed silicate glass pane forms a fire-resistant pane, which is supported on the holding frame by additional protruding holding tongues. In the event of a fire, this fire-resistant pane should ensure even heating and absorb thermal energy so that the glass pane element underneath can withstand the fire for longer. Polyvinyl butyral or another suitable organic plastic is proposed for bonding the fire-resistant pane to the glass pane element. When exposed to heat in the event of a fire, the adhesive layer melts, so that the mechanical connection between the fire-resistant pane and the glass pane element is released. The fire-resistant pane is now only held in position with the help of the holding elements attached at certain points. This prevents dangerous temperature differences and thus tensions from occurring in the fire protection pane and, on the other hand, the length changes

The fire protection pane's properties are not transferred to the glass pane element.

However, fire protection panes of this type with the corresponding brackets cannot prevent the formation of thermal bridges between the fire protection pane and the glass pane element, as these two elements are in direct surface contact even when the adhesive layer is melted. Furthermore, the bracket is not suitable for absorbing large forces and the proposed frame construction is only suitable for vertical installation.

It is an object of the present invention to propose a fire-resistant glazing and an associated holder which is suitable for horizontal installation, in particular in floor constructions, and in which, in the event of a fire, direct thermal bridges between the fire-resistant pane and the glass pane element are prevented and the service life of the glazing in the event of a fire is increased.

This object is achieved by the features defined in the characterizing part of claim 1. Advantageous developments of the invention result from the features of the dependent claims.

The design of the fire protection glazing and the holder according to the invention has the advantage that in the event of a fire and when the adhesive layer between the fire protection pane and the glass pane element softens, the fire protection pane falls onto the support surfaces on the retaining strips, which are arranged with a vertical free distance from the outer surface of the fire protection pane. This opens up a gap between the inner surface of the fire protection pane and the glass pane element, and there is no longer any direct contact between the fire protection pane and the glass pane element. As the temperature increases, the adhesive present in this gap decomposes and thus consumes thermal energy. The air cushion extending over the entire inner surface of the fire protection pane acts as an additional

Thermal insulation. The glass pane element above the fire protection pane or the air cushion retains its full strength over a long period of time, so that building elements of fire protection class G30 and higher can be easily created.

By arranging a free space between the edge surfaces of the fire protection pane and the frame, the advantage is achieved that the fire protection pane is not exposed to any stresses due to thermal expansion when heated, since the fire protection pane can expand freely. This

&iacgr;&ogr; applies even if the adhesive layer is still intact and even if the adhesive bond has been destroyed and the fire protection pane has fallen onto the support surfaces of the retaining strips. The width of the support surfaces of the retaining strips is at least twice as wide as the width of the free space between the edge surfaces of the fire protection pane and the frame.

Advantageously, a damping element is placed on the support surfaces of the retaining strips for the fire protection pane, whereby this is located in the free space between the outer surface of the fire protection pane and the support surfaces of the retaining strips. These damping elements can be made of a ceramic material, for example, and prevent damage to the fire protection pane after the adhesive connection has been destroyed, but also prevent direct heat transfer from the retaining strips to the fire protection pane that has fallen down and is resting on the support surfaces.

The fire protection pane can consist of a simple fire protection safety glass, but can also be constructed in several layers, whereby, if designed appropriately, foaming intermediate layers can also be present in a known manner. All types of known, conventional glazing can also be used as a glass pane element, i.e. a laminated glass pane, an insulating glass pane or even a single glass pane can be used. In the case of fire protection laminated or insulating laminated glass, the individual panes can consist of simple float glass or be tempered or partially tempered. It is certainly advantageous if at least one of the panes of the

Glass pane element consists of toughened safety glass. The choice of structure and design of the glass pane element depends in a known manner on the vertical load and the load factors, e.g. whether the plate-shaped structural element formed by the fire-resistant glazing and the bracket is only walked on by people or, in extreme cases, also driven over by heavy vehicles. By installing elastic intermediate elements between the edges and edge surfaces of the glass pane element and the frame, the load-bearing capacity of the plate-shaped structural element can also be adapted to the load factors in a known manner. The elastic intermediate elements also ensure even load transfer between the glass pane element and the frame on which the glass pane element is placed.

In the following, the invention is explained in more detail using an embodiment with reference to the accompanying drawing.

The illustrated Fig. 1 shows a cross section through the edge region of a plate-shaped structural element 1 according to the invention, which comprises a fire-resistant laminated glass 2, 3 and a holder in the form of a frame 6. The fire-resistant laminated glass 2, 3 is only partially shown and only one side region of the frame 6. The frame 6 is embedded in and connected to a floor construction 5 with a walkable and/or driveable surface 24. In the example shown, the frame 6 is a steel frame which is arranged on all sides around the fire-resistant laminated glass 2, 3. The fire-resistant laminated glass, which consists of a glass pane element 2 and a fire protection pane 3, is arranged within this frame 6. In the example shown, the glass pane element 2 is constructed from three tempered safety glasses 17, 18 and 19 which are glued to one another via the intermediate layers 25. The fire protection pane 3 is arranged on the lower side of the glass pane element 2 facing the possible fire side and is also glued to the glass pane element 2 via an intermediate layer 27. The connection of the individual panes of glass 17, 18, 19 and 3 with one another

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other, is carried out in a known manner using adhesive bonds, for example using a thermoplastic adhesive film made of polyvinyl butyral or another suitable connecting agent. The glass pane element 2 can have any dimensions and in the example shown has, for example, a length of 200 cm and a width of 170 cm. The length and width of the fire protection pane 3 are smaller, so that the edge area 4 of the fire protection pane 3 is set back from the edge surface 20 of the glass pane element 2. In the example shown, an edge surface 21 of an edge area 4 of the glass pane element 2 with a width of approx. 3 cm is exposed. This

The exposed edge region 7 of the glass pane element 2 rests on holding surfaces of the frame 6. In this way, the fire-resistant glazing, which is formed from the glass pane element 2 and the fire-resistant pane 3, is inserted approximately horizontally into the floor construction 5. Elastic intermediate elements 22 and 23 are inserted between the edge surfaces 20 and the edge surfaces 21 of the glass pane element 2 and the frame 6, which serve to optimally transmit the forces between the glass pane element 2 and the frame 6 and to compensate for differences in length. These elastic intermediate elements 22, 23 can consist of a heat-resistant elastomer, e.g. a silicone profile or another suitable material, e.g. a silicone hose or a ceramic fiber cord. In the area of the surface 24, the gap between the frame 6 and the glass pane element 2 is filled with a permanently elastic sealing compound 29, for example a fire-resistant silicone compound. A free gap 15 is formed between the edge surface 14, the fire protection pane 3 and the frame 6, which gap is so wide that the edge surface 14 of the fire protection pane 3 does not come into contact with the frame 6 under any circumstances. This allows the free movement of the fire protection pane

3 guaranteed in case of fire.

A retaining strip 10 is arranged on a lower part 9 of the frame 6, which in the example shown runs along the entire circumference of the fire protection pane 3. This retaining strip 10 overlaps the area of the edge

4 of the fire protection pane 3 and has a support surface 11. This support

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surface 11 is directed against the outer surface 12 of the fire protection pane 3 and positioned with a vertical free distance to this outer surface 12. This vertical free distance between the support surface 11 on the retaining strips 10 and the outer surface 12 on the fire protection pane 3 in the assembled state can be one to several millimeters depending on the design. Damping elements 16 are attached all around or partially to the support surfaces 11, which in the example shown consist of flexible ceramic strips. These damping elements 16 protect the fire protection pane 3 from damage and also prevent direct heat transfer between the retaining strips

&iacgr;&ogr; 10 and the fire protection pane 3 resting on the damping elements 16 in the event of fire.

The plate-shaped building element 1 shown is constructed in such a way that it has a high fire resistance against a fire source beneath the building element 1. It is therefore particularly suitable for installation as a translucent floor slab above fire-prone rooms below. If a fire source occurs beneath the plate-shaped building element 1, the fire protection pane 3 is directed towards this fire source. Initially, the fire protection pane 3 stores a certain amount of heat and heats up. At temperatures above 100 ^° C, the intermediate layer 27 made of polyvinyl butyral used in the example shown begins to melt until the adhesive layer 27 has reduced its adhesion to such an extent that the fire protection pane 3 falls down under its own weight onto the support surfaces 11 or the damping elements 16 on the retaining strips 10. This separation between the fire protection pane 3 and the glass pane element 2 occurs in the event of a fire before the glass pane element 2 is significantly heated. As a result of this process, a free space is created between the inner surface 13 of the fire protection pane 3 and the lower surface 28 of the glass pane element 2 and there are no longer any direct thermal bridges between the fire protection pane 3 and the glass pane element 2. If the fire protection pane 3 is heated further, the intermediate layer 27 is decomposed and evaporated, whereby additional thermal energy is absorbed. The air-filled space between the fire protection pane 3 and the glass pane

The fire protection pane 2 serves as a heat insulator, so that a high fire resistance period is achieved with the plate-shaped construction element 1 according to the invention. If protection against heat radiation is also desired on the upper side of the construction element 1 facing away from the fire, the fire protection pane can also be designed as a multi-layer pane with one or more intermediate fire protection layers which foam up in the event of a fire. This is possible in a simple manner, since the adjustment of the frame 6 or the retaining strips 10 is possible in a very simple manner.

In summary, the innovation relates to fire protection glazing which is intended as a structural element 1 for horizontal installation in floor structures 5. The structural element 1 comprises a frame 6 and a glass pane element 2 held in this frame 6. The glass pane element 2 has a strength which allows walking and/or driving over it. A fire protection pane 3 glued to the glass pane element 2 comes loose in the event of a fire, and an insulating gas cushion is formed between the fire protection pane 3 and the glass pane element.

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Claims (5)

1. Fire protection glazing ( 2 , 3 ) and holder for a plate-shaped building element ( 1 ), with a multi-layered glass pane element ( 2 ) and a fire protection pane ( 3 ) glued to this glass pane element ( 2 ) on the fire side, the fire protection pane ( 3 ) being set back along the edge ( 4 ) relative to the glass pane element ( 2 ), characterized in that the fire protection glazing ( 2 , 3 ) is inserted approximately horizontally into a floor construction ( 5 ) and is placed on a frame ( 6 ), the fire protection pane ( 3 ) being directed downwards and the edge regions ( 7 ) of the glass pane element ( 2 ) resting on an approximately horizontal holding surface ( 8 ) of the frame ( 6 ), holding strips ( 10 ) are arranged on the lower part ( 9 ) of the frame ( 6 ), which hold the edge region ( 4 ) of the Fire protection pane ( 3 ) overlap and these retaining strips ( 10 ) have support surfaces ( 11 ) which are arranged at a vertical, free distance from the outer surface ( 12 ) of the fire protection pane ( 3 ). 2. Fire-resistant glazing ( 2 , 3 ) and holder for a plate-shaped building element ( 1 ) according to claim 1, characterized in that a free intermediate space ( 15 ) is formed between the edge surfaces ( 14 ) of the fire-resistant pane ( 3 ) and the frame ( 6 ) and the width of the support surfaces ( 11 ) of the holding strips ( 10 ) is at least twice as large as the horizontal width of this free intermediate space ( 15 ). 3. Fire protection glazing ( 2 , 3 ) and holder for a plate-shaped component ( 1 ) according to claim 1 or 2, characterized in that a damping element ( 16 ) is inserted between the support surfaces ( 11 ) of the holding strips ( 10 ) for the fire protection pane ( 3 ) and the outer side ( 12 ) of the fire protection pane ( 3 ). 4. Fire-resistant glazing ( 2 , 3 ) and holder for a plate-shaped structural element ( 1 ) according to one of claims 1 to 3, characterized in that at least one of the panes ( 17 , 18 , 19 ) of the glass pane element ( 2 ) is a safety glass pane. 5. Fire-resistant glazing ( 2 , 3 ) and holder for a plate-shaped building element ( 1 ) according to one of claims 1 to 4, characterized in that elastic intermediate elements ( 22 , 23 ) are inserted between the edge and marginal surfaces ( 20 , 21 ) of the glass pane element ( 2 ) and the frame ( 6 ).