DE3701808C2 - - Google Patents

Description

The invention relates to frameless glazing (structural glazing), the one or more Existing glazing without overlapping the edges Frame over a load-bearing seal, especially from Silicone rubber, attached to metal facade profiles is.

With the known under the technical term "structural glazing" In terms of construction, glazing is frameless on two or four Sides on facade profiles such as facade posts and Facade bars attached, such as in DE-OS 35 41 730 is shown. The glazing consists of a Pane or a heat or soundproof glazing several panes is placed directly on the facade profiles sealed, the seal not only sealing function exercises, but also static functions like that Transmission of wind loads takes over and partly that Own weight of the glazing bears. The sealing takes place especially with a one- or two-component Silicone rubber.

Fire tests on frameless glazed window elements Single-pane safety glass (toughened safety glass) or toughened glass show that in unfavorable conditions, for example a slow rise in temperature in the fire chamber, the load-bearing Sealing failed and detached from the substructure peels off before the pane breaks. It therefore consists in Fire traps the danger of falling out whole Disc elements. The reason for this is that the temperature in the profiles of the supporting structure Destruction temperature of the seal reached before in Glass higher and therefore also destructive Temperature gradients arise in the disks. For ESG more than 150 K temperature differences are used.

The invention has for its object a frameless To create glazing, in which no fire Falling out of whole disc elements occurs.

This object is achieved in that the Pane or, in the case of multi-pane glazing, a pane a toughened safety glass (ESG) or a partially toughened one Is glass, and that between the pane of toughened glass or partially tempered glass and the facade profiles thermally conductive connection from a surface limited element is arranged, the thermal Conductivity is greater than that of sealing and that can not transmit any significant mechanical forces.

A through the thermally conductive connection Induction of a destructive temperature gradient into the glass pane, so that in the event of a fire the pane is out ESG temperatures occur which can destroy the pane effect before the load-bearing seal is destroyed. At the same time occurs through the arrangement of the Connecting elements between the disc and the Facade profiles no deterioration in the thermal insulation Glazing and no reinforcement of the connection of the pane on the facade profiles.

The connecting element preferably consists of a thin one Metal element, for example with a width of approx. 10 mm.

According to a preferred embodiment, at most one Metal connection element provided per pane edge. Each depending on the size of the pane, a Metal connecting element for a washer should be sufficient.

The connecting element preferably consists of a Sheet metal or a metal mesh.

The connecting element is used for multi-pane glazing  preferably with one end in the edge of the disc glued in from ESG.

The connecting element is designed so resilient that it with mechanical stress on the glazing Wind forces, shock, or the like. No constraints and thus too Glass break comes. Furthermore, the connecting element is not visibly attached to the pane.

Embodiments of the invention are described below the drawing explained in more detail. It shows:

Fig. 1 is a frameless single glazing and

Fig. 2 is a frameless double glazing.

Fig. 1 shows in cross section a supporting metal profile 10 of a facade structure, not shown. Disks 12 and 14 made of single-pane safety glass (ESG) are supported on this load-bearing metal profile 10 via spacer profiles 16 and 18 made of silicone. The connection between the metal profile 10 and the washers 12 and 14 takes place via load-bearing seals 20 and 22 , which are arranged between the metal profiles and the washers. The opposite edges of the panes 12 and 14 are sealed by a weather seal 24 .

In order to induce a destructive temperature gradient in the event of fire between the load-bearing metal profile 10 and the panes 12 , 14 made of ESG, thermally conductive connecting elements 26 and 28 are arranged. The thermally conductive connecting element 26 is Z-shaped and communicates with one free leg with the metal profile 10 and with the other free leg with the back of the pane 12 . The thermally conductive connecting element 28 is U-shaped and rests with its free legs on the metal profile 10 or the disk 14 . When the metal profile 10 heats up in the event of a fire, heat is transferred into the pane via the connecting elements, so that the panes 12 , 14 reach temperatures at which they break before the seals 20 , 22 are destroyed. This ensures that the panes 12 and 14 cannot fall as a whole from the facade elements, but only in fragments. The connecting elements 26 and 28 can consist of a thin metal sheet or a flexible metal mesh and have a width of approximately 10 mm.

Fig. 2 shows a load-bearing metal profile 30 , to which multiple pane glazings 32 and 34 are attached without a frame. The glazing 32 consists of an outer pane 36 made of ESG and an inner pane 38 made of non-tempered float glass. Between the discs 36 and 38 is arranged a Glasab spacers 40 and the connection of the discs 36 and 38 via a bearing sealing 42nd The attachment of the glazing 32 takes place via an inner load-bearing seal 44 , which is arranged between the back of the disc 38 and the front of the metal profile 30 . A spacer profile 45 made of silicone is also arranged between the disk 38 and the metal profile 30 .

The glazing 34 consists of an inner pane 46 made of ESG and an outer pane 48 made of non-tempered float glass. Between the discs 46 and 48 is arranged a Glasab spacers 50 and the connection of the discs 46 and 48 takes place via an outer bearing sealing 52nd The glazing 34 is fastened to the metal profile 30 via an inner load-bearing seal 54 . A spacer 56 made of silicone is arranged between the metal profile 30 and the glazing 34 . A weather seal 57 is provided between the opposite edges of the panes 36 and 48 .

In order to induce a destructive temperature gradient in the event of fire from the metal profile 30 into the outer pane 36 made of toughened safety glass of the glazing 32 , a Z-shaped thermally conductive connecting element 58 is arranged, which has a free leg on the metal profile 30 and on the other free leg the disc 36 abuts. A thermally conductive connecting element 60 is arranged between the pane 46 of the glazing 34 and the metal profile 30 , which is also Z-shaped and rests with one leg on the metal profile and with the other leg on the pane 46 made of toughened safety glass. The connecting elements 58 and 60 can, as in the exemplary embodiment according to FIG. 1, consist of sheet metal or flexible metal mesh and have a width of 10 mm.

Claims (6)

1. Frameless glazing (structural glazing), wherein the glazing consisting of one or more panes without the edges overlapping frame is attached to a facade seal made of metal via a load-bearing seal, in particular made of silicone rubber, characterized in that the pane ( 12 , 14 ) or in a multi-pane glazing ( 32 , 34 ) a pane ( 36 , 46 ) is a single pane safety glass (ESG) or a partially toughened glass, and that between the pane ( 12 , 14 , 36 , 46 ) made of toughened glass or partially toughened glass and the facade profiles ( 10, 30 ) are arranged a thermally conductive connection consisting of an area-limited element ( 26 , 28, 58, 60 ), the thermal conductivity of which is greater than that of the seal and which cannot transmit any significant mechanical forces. 2. Frameless glazing according to claim 1, characterized in that the connecting element ( 26 , 28 , 58 , 60 ) consists of a thin metal element. 3. Frameless glazing according to claim 1 or 2, characterized characterized that at most one Connection element is arranged per pane edge. 4. Frameless glazing according to one of claims 1 to 3, characterized in that the connecting element ( 26 , 28 , 58 , 60 ) consists of a metal sheet or a metal mesh. 5. Frameless glazing according to one of claims 1 to 4, characterized in that in multi-pane glazing ( 32 , 34 ) the connecting element ( 58 , 60 ) is glued with one end in the edge back of the pane ( 36 , 46 ) made of toughened safety glass. 6. frameless glazing according to one of claims 1 to 5, characterized in that the Connecting element is Z-shaped or U-shaped.