CH708354B1 - Fire protection component - Google Patents

Abstract

The fire protection component (1) has at least one fire protection glass (2) and a frame (3). The fire protection glass is held in a receptacle (12) of the frame, so that the front side of the fire protection glass a rebate space (14) remains, wherein the frame has at least two thermally separated profiles. The fire protection glass is fixed with an adhesive (10) in the receptacle (12).

Description

Description: The invention relates to a fire protection component, comprising at least one frame and at least one fire protection glass.

EP 1 582 686 shows a frame construction for fire protection elements with a frame and a surface element (for example fire protection glass), wherein a metallic holder is arranged between the frame and the surface element. Furthermore, there may be an intumescent layer between the frame and the metallic holder, which in case of fire foams when a threshold temperature is exceeded and presses the metallic holder against the surface element. However, a thermal bridge is formed by the metallic holder, which inevitably causes an increase in the temperature on the side of the fire protection element facing away from the fire. In case of fire, the metallic holder can also bend due to the strong heat and the load with the surface element. This makes it possible that the intumescent layer no longer gas-tight closes and there is an undesirable gas and / or temperature passage to the side facing away from the fire.

It is the object of the invention to provide a fire protection component available, which reduces in the event of fire, a temperature or energy transfer from the fire-facing side to the side facing away from fire of the fire protection component.

This object is achieved by a fire protection component with a fire protection glass and a frame as defined in claim 1.

The fire-resistant glass is a glass with fire-resistant properties, the fire-resistant glass need not consist exclusively of glass material, it may, for example, also comprise a plastic (i.e., in particular a polymer, possibly with, for example, inorganic fillers), e.g. Acrylic glass as part of a laminated glass. The fire protection component can also be referred to as fire-resistant glazing.

The fire protection component has at least one frame and at least one fire-resistant glass, for example in the form of a fire protection pane or a composite fire protection pane. The fire protection glass is held in a receptacle of the frame, so that the front side of the fire protection glass remains a void. This white space is also called a seam. The frame has at least two thermally separated profiles - one on the fire side and one on the side facing away from the fire, where it is not necessary to determine from the outset which side is the fire side and which is the side away from the fire - the profiles, for example, via at least one connecting web can be connected to each other; Alternatively, they can also be connected to one another only via the fire protection glass and, for example, via a room element (wall or the like). The fire protection glass is fixed with an adhesive in the receptacle.

An adhesive, also referred to as an adhesive, is an organic or inorganic material which connects elements (in particular flat) by adhesion to one another. The adhesive can be, for example, a glue, another solvent-based adhesive or dispersion adhesive before curing, a chemically curing adhesive (in particular a polymerization adhesive), or a hot melt adhesive, in particular a thermoplastic or another suitable adhesive; combinations are also conceivable. Also so-called reactive hot-melts, which cure completely chemically after thermoplastic application and are converted to a thermoset, are conceivable. In particular, adhesives having a high thermal decomposition point are suitable. The adhesive may be, for example, a silicone adhesive, for example an adhesive according to the standard DIN EN 15 434: 2010-07 (standard for sealants and adhesives for glued glazing). However, any other adhesive (for example, from the list mentioned above) may also be used. The type of adhesive is secondary - important is its sealing and / or adhesive function during the fire.

If the adhesive has thermoplastic properties and liquefies when heated, it is, for example. Arranged so that it is protected from direct heat or fire in the event of fire.

A thermal separation of the profiles of the frame in combination with a fixation of the fire glass by the adhesive causes a heat or energy transfer is reduced from the fire side to the fire side facing away from the fire glass, with a possible connecting web is made of a material, which has a low thermal conductivity. In this way, it is possible that the profile on the side facing away from the fire is subjected to little thermal stress and the fire-resistant glass with the adhesive remains functionally fixed to the profile. Optionally, a connecting bar can melt in case of fire (if it is made of a thermoplastic) and thereby further support the thermal separation in case of fire.

In contrast, for example, a one-piece frame system would have the disadvantage that the heat is transported faster to the side facing away from fire. This would lead to premature deterioration of the fixation by the adhesive, since the adhesive may prematurely heat up and melt or decompose, whereby the fire protection glass can be released from the frame system. Furthermore, tensions are built up by one-sided heat loads in a one-piece frame system, which can reduce or even solve the fixation by the adhesive.

From the prior art such as EP 1 582 686 thermally isolated frame systems are known in which a surface element is held by means of a metallic holder. Metals have a thermal conductivity of approximately (10-400) W / (mxK). The metallic holder thus inevitably creates an at least selective thermal bridge between the profiles of the frame system. In this way, the profile is also thermally stressed on the side away from the fire, and thus induced stresses can lead to failure of the fire protection element. Furthermore, heated metallic holders can lose their shape and thus their holding effect due to high loads in case of fire.

Embodiments of the fire protection component have a connecting web as the only connection between the profiles of the frame. This compound is elastic, since such a connecting web can be made of plastic. Plastics have a thermal conductivity of (0.02-0.5) W / (m x K). This value is smaller by two orders of magnitude than that of metallic conductors. As a result, the heat transfer is significantly reduced in comparison to the prior art with metallic holders, which can significantly reduce induced stresses on the frame at least on the fire side facing away from the fire protection component.

Furthermore, embodiments of the fire protection component have the advantage that the adhesive is at least on the side away from the fire side due to the thermal separation of the profiles as described above not thermally or only slightly impaired. This makes it possible that the fire-resistant glass remains fixed in the frame by the adhesive and no additional stresses arise. In other words: In embodiments of the fire protection component, the profiles remain thermally separated even in case of fire, since neither a possibly existing connecting web still on the fixing, flexible adhesive, a thermal bridge between the separate profiles can arise. This makes it possible to minimize heating of the fire side facing away from the fire protection glass and to extend a fire resistance of the fire protection component.

It has surprisingly been found, in particular, that an adhesive bond has sufficient elasticity to accommodate minor and medium differences in the thermal expansions of the two profiles and the fire protection glass. In case of fire, if the differences can be large under certain circumstances, the adhesive on the fire side will first loosen or decompose, which makes it possible for the fire-resistant glass to remain well in the frame on the side away from the fire and, in contrast to a metallic clip which can fail completely in a fire-induced deformation, still provides for a stable support of the fire-resistant pane.

The adhesive can adhere and fix the fire protection glass to the frame during a total fire resistance time. The fire resistance time is the time during which the fire protection component remains functional in case of fire or fire test. This means that, among other things, a heat-insulating effect and a partial gas seal is ensured during the fire resistance time by the fire protection component.

The use of adhesive for fixing is particularly advantageous since the adhesive has a certain flexibility even in the fixing state. This flexibility is needed above all in the event of a fire, since the frame and the fire-resistant glass expand to different extents. Due to the different expansion coefficients there is a distortion of a fixation point between the frame and fire-resistant glass. This distortion puts an additional burden on the stability of the fixation (by resulting stress). The fixing adhesive can absorb the stresses and keeps the fire-resistant glass in the frame even in case of fire.

The rebate space between the frame and the front of the fire glass allows especially in case of fire, a different extent of frame and fire glass without them (frame and fire glass) against each other and additionally generate stress.

The adhesive fixes the fire protection glass during the entire fire resistance time close to the frame in the recording. This makes it possible that parts of the frame, such as a glass retaining strip can melt in the event of fire without the fixation of the fire-resistant glass suffers.

The recording takes on an edge region of the fire protection glass, in this way a Randeinstand is formed - that is, the edge fence is the edge region of the fire protection glass, which is located in the recording. The edge recess is formed by the front side of the fire-resistant glass and an edge region of the fire-resistant glass in the vicinity of the edge.

A foamable seal can be arranged on the front side of the fire protection glass, so that foaming at least partially closes a passage formed by the rebate. The adhesive causes in particular that, for example, the frame in conjunction with the foamable gasket prevents undesired passage of gas from the side facing the fire, since it firmly fixes the fire protection glass in the frame and prevents the formation of gaps as openings to the fire.

The seal foams only from a certain temperature, for example above about 100 ° C. Depending on the chemistry of the foaming gasket (eg silicates, phosphates, expanded graphites or vermiculites), the gasket starts to foam up to 400 ° C at 100 ° C.

That is, only in case of fire, the seal is foamed. When foaming increases the volume of the seal (density decreases) and the rebate space between the front of the fire protection glass and the frame is at least partially closed gas-tight. This makes it possible to prevent a gas transfer to the fire-facing side and thus counteract free openings and / or columns. Furthermore, no fire-promoting oxygen reaches the fire-facing side of the fire protection glass or the entire fire protection component.

The foamed seal can mechanically stabilize the fire-resistant glass by pressure exerted elastically from the front side.

Furthermore, the foamed seal can also act thermally insulating. Among other things, it also protects the adhesive on the side away from the fire from decomposition by burning or the use of thermoplastic adhesive against melting. This makes it possible that the fire-resistant glass remains fixed to the frame at least on the side away from the fire during the entire fire resistance time. This means that on the firing side a glass retaining edge can be melted off without weakening the fixation in the frame.

The fire protection glass is a surface element having two substantially parallel large areas, which are also called flat sides. The edges of the two flat sides are connected to one another via an end face. In this case, the end face has a smaller area than the flat sides, and one dimension corresponds to the thickness of the fire protection glass. By "front side" is meant in this text, the circumferential surface between the flat sides, which is also called "edge" or "narrow side" of a fire-resistant glass or a disk composite, or a surface thereof. An edge region of the fire-resistant glass, which is arranged in the frame, can also be referred to as a edge recess. The adhesive can be, for example, a "structural sealant" adhesive, as is known for "structural glazing". Such adhesives have a particularly high elasticity with very good adhesive properties. This means that, for example, different differences arising in the event of temperature differences are compensated particularly well by the adhesive.

This also makes it possible to obtain a good fixation of the fire protection glass in the frame without openings or cavities between the frame, adhesive and fire protection glass. In this way it can be prevented that, as in the use of a metal clip according to the prior art, openings occur which can adversely affect the gas-tightness of the fire-resistant glazing.

The adhesive may for example fix at least one edge region of the fire protection glass in the receptacle. In this case, the adhesive is arranged mainly on the flat side of the edge collar and not the front side of the fire protection glass. This makes it possible that the foaming seal in the event of fire can press the front side directly against the fire glass and does not have to act indirectly against the adhesive.

The adhesive can fix the Randeinstand on the frame at several points, it is possible that the adhesive is disposed on opposite flat sides. It is of course also possible that the adhesive is arranged offset on the two flat sides of the edge Einstandes.

The adhesive may, for example, also be arranged completely along the entire lateral (flat side) edge recess and thus fix the fire protection glass in the frame. This makes it possible to support the foamed gasket in its gas-sealing effect.

Regardless of the nature of the arrangement (opposite, offset, full circumference) of the adhesive in the frame along the lateral (flat side) Randeinstandes the adhesive must fix the fire protection glass at least on the fire side facing away from the frame.

The fire protection glass, for example, have a composite fire protection pane. A composite fire protection pane has at least two transparent carriers (panes), in particular glass panes, between which a fire protection layer is arranged. The fire protection layer absorbs energy in case of fire and thus protects the feu-erabgewandte disc from heating and / or shattering. The fire protection layer may comprise, for example, a hydrogel, an alkali metal silicate or another transparent material. The fire protection layer can be foaming in the event of fire, it can also have a cooling and / or insulating effect or combine all these properties.

The fire-resistant glass can also be designed as another laminated glass with a fire-resistant glass pane, for example as an insulating glass or an anti-fire-protection pane, for example as taught in DE 20 2012 012 285.1. In the case of the insulating glass, a cavity between at least two spaced disks is filled with air or inert gas. The disks can be thermally toughened glass panes. The fire protection glass does not necessarily have to consist of glass, it can also have a suitable plastic.

As a further alternative, the fire-resistant glass can be designed as a single-pane safety glass, optionally with a coating.

The frame may have at least two thermally separated profiles, wherein the thermally separated profiles may be configured in particular as aluminum profiles. The thermally separated profiles, like the frame itself, may include various materials such as steel, aluminum, plastic or wood. They can be designed in various ways to form the receptacle for the fire-resistant glass.

Further preferred embodiments will become apparent from the dependent claims.

In the following, the subject invention based on preferred embodiments, which are illustrated in the accompanying drawings, explained in more detail. It shows schematically:

Claims (12)

Fig. 1 is a sectional view of a fire protection component. Fig. 1 shows schematically a sectional drawing of a fire protection component 1, wherein a fire protection glass 2 is held or fixed in a receptacle 12 of a frame 3. The fire protection glass 2 is a composite fire protection pane 2. The frame 3 has two aluminum profiles 34 which are thermally separated by a connecting web 13. The aluminum profiles 34 have, for example, a glass retaining strip 31 and / or a profile stop / profile flap 32, which together form the receptacle 12 in the form of a groove running along the frame 3 with a width slightly greater than the thickness of the composite firing pane. With the aid of a profile seal 33, between the aluminum profile 34 and the composite fire protection pane 2, the composite fire protection pane 2 is connected to the frame 3; the seal may be connected to the frame by means of appropriate structural features, as shown in the figures. The profile seal 33 is circumferentially disposed on the edge of the composite fire protection pane 2 and is located on the edge of the edge. The edge recess is the edge region of the composite fire protection pane 2, which is located in the receptacle 12. The peripheral edge is formed by an end face 22 of the composite fire-resistant pane and an edge region of the composite fire-resistant pane in the vicinity of the edge. In the event of non-firing, the profile seal 33 assists in holding the composite fire protection pane 2 in the frame 3. The composite fire protection pane 2 is held in the receptacle 12 of the frame 3 in such a way that the seam of the composite fire protection pane 2 remains a rebate space 14. The rebate 14 can compensate for a different extent of frame 3 and composite fire protection panel 2. A foamable seal 11 is arranged on the front side of the composite fire protection pane 2 in the receptacle 12. In case of fire, the seal 11 foams from reaching a certain temperature of eg. At least 100 ° C and presses against the end face 22 of the composite fire protection pane 2. This closes a passage from the fire side on the side facing away from the fire, which may exist if the adhesive 10 (see below) is only selectively and not circumferentially mounted or partially destroyed and the profile seal 33 incompletely seals or destroyed in case of fire. The foamable seal 11 is, for example, arranged circumferentially along the entire end face of the composite fire protection pane 2, that is to say also on opposite sides. The foamed seal 11 presses against the composite fire protection pane 2, wherein there is no contact between the seal 11 and the composite fire protection pane 2 before the fire. The seal 11 thus supports not only the aforementioned sealing effect but also the fixation of the composite fire protection pane 2 in the frame 3. The fixation of the composite fire protection pane 2 in the frame 3 is effected by an adhesive 10. The adhesive 10 fixes a part of the flat side and the front side of the composite fire protection pane 2 on the frame. The fixation is slightly flexible, whereby, for example, during the foaming of the seal 11 minimum position changes of the composite fire protection pane 2 in the frame 3 can be yielded without the composite fire protection pane 2 falls out of the frame 3. A freedom of movement for the change in position is made possible, inter alia, by the rebate space 14. The adhesive may, for example, be a silicone adhesive, for example an adhesive according to the standard DIN EN 15 434: 2010-07 (standard for sealants and adhesives for glued glazings). For example, the adhesive may also include GE's SSG4600 UltraGlaze. But it can also be used any other adhesive. The type of adhesive is secondary, but important is its sealing and adhesive function even during the fire. In case of fire, it is possible that a part of the frame 3 (for example, glass retaining strip 31 or profile stop / profile flaps 32) melts through the fire. During the melting, the temperature near the seal 11 is so high that it foams. By the foamed seal 11, the adhesive 10 is protected on the fire side facing away from the composite fire protection panel 2 from direct contact with the fire / fire and can fix the composite fire panel 2 on the frame profile remote from the fire 34. The composite fire protection pane 2 is here a composite fire protection glass pane, which consists of five glass panes 20 with a fire protection compound 21 between adjacent glass pane 20. The fire protection compound 21 foams up in the event of fire, becomes cloudy and blocks infrared radiation and also absorbs thermal energy. claims 1. fire protection component (1), comprising at least one frame (3) and at least one fire protection glass (2), wherein the fire protection glass (2) in a receptacle (12) of the frame (3) is held so that the front side of the fire protection glass (2) a rebate space (14) remains, wherein the frame (3) has at least two thermally separated profiles, characterized in that the fire protection glass (2) is fixed with an adhesive (10) in the receptacle. 2. Fire protection component (1) according to claim 1, characterized in that the thermally separated profiles are aluminum profiles. 3. Fire protection component (1) according to one of the preceding claims, characterized in that the fire protection component (1) in the event of fire foamable seal (11) the front side of the fire protection glass (1), so that the foamed seal through the rebate (14) formed Closing passage at least partially. 4. Fire protection component (1) according to one of the preceding claims, characterized in that the adhesive (10) fixes at least one edge region of the fire protection glass (2) in the receptacle (12). 5. Fire protection component (1) according to claim 4, characterized in that the adhesive (10) fixes two opposite edge regions of the fire protection glass in the receptacle (12). 6. Fire protection component (1) according to claim 4 or 5, characterized in that the adhesive (10) the fire protection glass (2) fully fixed in the receptacle (12). 7. Fire protection component (1) according to any one of claims 3-6, characterized in that the adhesive (10) is protected in case of fire at least on the side facing away from the fire by the foamable in case of fire seal. 8. Fire protection component (1) according to one of the preceding claims, characterized in that the fire-resistant glass (2) is a fire-resistant glass pane, possibly with a coating. 9. Fire protection component (1) according to any one of claims 1-7, characterized in that the fire protection glass (2) is a composite fire protection pane or an insulating fire protection pane. 10. Fire protection component (1) according to one of claims 1-7, characterized in that the fire protection glass (2) has a composite with at least one between two panes (20) arranged fire protection layer (21). 11. Fire protection component (1) according to one of the preceding claims, characterized in that the at least two thermally separated profiles by at least one connecting web (13) are interconnected. 12. fire protection component (1) according to claim 11, characterized in that the connecting web (13) comprises a plastic.