The invention relates to a fire safety-structural element for doors or windows with at least one fire safety glass unit with fittings for fastening and/or closure elements as a door or window leaf, the fire safety glass unit being insertable into an opening with an architrave frame of a building closing off such.
In the construction industry glass units are very frequently employed, in particular for door or window leaves, and also for partitioning walls. These glass units are most often installed into a frame, on which are disposed corresponding fittings for fastening and/or closure elements. This glass and frame unit is subsequently connected by means of the fittings with the building, or is held thereon. A corresponding arrangement for a door is disclosed for example in U.S. Pat. No. 4,671,016. According to this arrangement, a pane of safety glass is clamped at the lower and upper edge in a frame element. The frame elements and the glass pane form a planar element in the shape of a door leaf, all parts being firmly connected with one another. The depicted door leaf is set into an opening in a building in a manner not shown and is encompassed by a known door frame with door architraves. This architrave frame, in turn, is fastened and supported on the building.
Such arrangement is incapable of developing a sufficient fire safety effects in the event of a fire. The disadvantage of this arrangement includes that the glass pane with the frame parts fixedly connected therewith expands upon heating and specifically in height as well as also in width. The joint gaps normally provided between door leaf and outer frame in such leaf arrangements, in particular doors, are incapable of absorbing these changes of length due to thermal expansion. In the case of glass doors, which are approved as fire safety doors, the joint gap is not permitted to be larger than a specified maximum dimension. This maximum joint gap is smaller than the change in length of the door leaf due to heating. In particular, in the direction of height of a door for example, the door leaf becomes seized in the architrave frame, or in the building, and the glass pane is destroyed through the generated compressive stress. Thereby any protective action against a fire event becomes inapplicable.
According to AT 004250 U1 it is also known to dispose on the architrave frame a sealing profile comprised of a material which foams when exposed to heat. In the event of a fire and under the impact of heat this sealing profile foams and closes off the joint gap between the architrave frame or door frame and the door leaf. This arrangement would in principle make possible providing a larger joint gap. However, in the case of fire safety doors implemented according to fire safety regulations, this is not permissible. In a door arrangement in which the door leaf is comprised of a simple glass unit without frame, this known arrangement is inoperative. When using a glass unit without intermediate foaming layer, the glass becomes also deformed in the plane of the glass pane in the event of fire. The side edges of the glass unit bend under the impact of heat and subsequently are no longer in the region of the foaming sealing profiles. Their sealing effect is therewith no longer ensured. Moreover, changes of length of the door leaf, due to thermal insulation, also lead to seizing of the glass unit and to the destruction of the same.
The present invention therefore addresses the problem of accomplishing in the event of fire a fire-resistant element with a fire safety glass unit for doors or for windows, in which the glass unit with conventional joint gaps is to be insertable into an architrave frame in an opening of a building. Changes of length and deformation of the glass unit and its frame parts due to heating can occur without the glass unit being destroyed or the fire safety action being reduced and the glass unit can be developed without a frame.
According to the invention this problem is solved. Advantageous further developments of the invention are evident in the claims.
Between at least one side edge of a glass unit and a fixed element of an architrave frame adjacent to this side edge, the invented fire safety-structural element comprises an additional element in the form of a telescoping element. This telescoping element comprises a first, stationary part, and a second, displaceable part, in which in the direction of the plane of the glass unit between the two parts of the telescoping element is formed a free interspace. In the event of fire, the two parts of the telescoping element are displaceable relative to one another in the direction of the plane of the glass unit. This disposition according to the invention of a telescoping element with two parts which are displaceable relative to one another advantageously permits changes of length and deformations of the elements, in particular of the glass unit and the architrave frame. The free interspace between the two parts of the telescoping element can be enlarged or reduced, whereby in the plane of the glass unit increases of the dimensions of the parts as well as also decreases of the dimensions can be compensated. Therewith it becomes possible to compensate via the telescoping element(s) various dimensional changes, which in the event of fire occur as a consequence of the different materials, however also as a consequence of the different expansion behaviors, in the course of time of a fire. This ensures that in the event of fire the joint gap between the glass unit and the adjacent architrave frame is closed off without the glass unit needing to be clamped in and being exposed to impermissible loading. One advantageous development of the invention provides that the fire safety glass unit is frameless and that the fire safety glass unit is comprised of a simple prestressed glass pane. However, laminated glass units with several glass panes can also be utilized. In the case of the combination of a frameless fire safety glass unit of a simple prestressed glass pane as the door leaf with the telescoping elements between door leaf and architrave frame, a fire resistant structural element can be built, which corresponds at least to the fire safety class E30 according to the European Standards EN 13501. A glass pane is advantageously utilized which has a thermal stress factor φ between 0.5 and 0.85 N/(mm2×K). The thermal stress factor is calculated from the parameters thermal expansion coefficient α, modulus of elasticity E and Poisson constant μ according to the formula φ=α·E/(1−μ). Such glasses are disclosed in DE 197 10 289 C1.
A useful implementation of the subject matter of the invention provides disposing an elastic part between the two parts of the telescoping element. This elastic part can be a formed body of an elastic material or an elastic element, for example a compression spring. The elastic part can absorb and compensate positive as well as also negative changes of length. An especially useful solution results if the elastic part is a formed body containing a material foaming under heat impact. In this case the elastic part can compensate changes of length occurring in the event of fire, which are greater than the elastic change of shape of the part alone. Such formed bodies are generally known in fire safety technology and are commercially available for example under the designation pad tape.
The invention further proposes that the telescoping element transversely to the plane of the glass unit has a width which is at least twice the thickness of the glass unit. This implementation offers the advantage that the edge regions of the glass unit can also be deformed relative to the plane and yet the joint gap region is sealed as desired without the glass unit needing to be clamped in and being destroyed. This is advantageous in particular in view of the use of a frameless, simple and prestressed glass pane as a door leaf.
A further development of the invention provides that in the outer region of the interspace one elastic part in the form of a tape, comprised of a material foaming under heat impact, is placed between the two parts of the telescoping element, these two tapes being disposed at a free spacing with respect to one another transversely to the plane of the glass unit. This disposition yields the advantage that, in the event of an abutment of one side edge of the glass unit on the second part of the telescoping element, a clearance is formed between the two tapes which can be utilized as additional buffer space. The two tapes are located outside of the plane of the glass unit.
The invention further proposes that the first part of the telescoping element is formed by a portion of the architrave frame with rectangular cross section and the second part of the telescoping element has a U-shaped cross section, the bottom face of the U-part being directed against an edge of the glass unit and the two shank faces of the U-part being guided on the first part of the telescoping element. The invention proposes moreover that between the first part of the telescoping element and the architrave frame a deformable part is emplaced. This deformable part is advantageously formed by a profile tape of mineral wool. Therewith the architrave frame, which normally is formed of metal, can also compensate form and length changes via this deformable part even under heating in the event of fire. The architrave frame can also be formed of another suitable material, for example wood. The rectangular cross section of the first part of the telescoping element ensures high stability of the architrave frame and forms simultaneously a suitable guidance for the displaceable second part of the telescoping element with U-shaped cross section. However, for the first part another cross section, for example a U-shaped cross section, can also be utilized. The bottom face of the U-shaped second part is stayed on the alternate part in the outer regions via the elastic elements. The surface region of the bottom face between the elastic elements is formed such that it is resilient and this resilient region is located opposite a side edge of the glass unit. Even in the presence of strong buckling of a side edge of the glass unit as a consequence of the heating, such side edge is still within the region of the resilient bottom face and it can be deformed in the event of a contact due to changes in length. Concurrently with the resilient deformations of the bottom face of the second part, in such event the two elastic elements at the outer regions of the bottom face are also compressed. If these two elastic elements contain a material which foams under heat impact, these two elements expand in the event of fire and bend the bottom face of the second part of the telescoping element additionally over the side edge of the glass unit. Thereby optimal closing off of the joint gap between glass unit and architrave frame is ensured and simultaneously too large a compressive stress is prevented from building up in the glass unit through the changes in length.
A further development of the invention provides that at least at the upper side edge of the glass unit a closure rail is disposed which encompasses the telescoping element. In an advantageous implementation the first part of the telescoping element is formed by the edge region of the glass unit or a rail firmly connected with the glass unit. The second part of the telescoping element is here comprised of a rail with U-shaped cross section, the bottom face of the U-part being directed toward the architrave frame and the two shank faces of the U-part being guided on side faces of the first part. This embodiment of the invention permits the application of the invented solution in elements, in which the architrave frame cannot be equipped with a telescoping element. However, it is also possible to combine the two solutions with one another, whereby in some cases optimization of the fire safety can be attained. This disposition according to the invention permits a length compensation at the joint gap in the bottom region or the side edge of the glass unit which has fastening elements. This can be done in particular if in the interspace between the two parts of the telescoping element an elastic part with material foaming under heat impact is installed. During normal use of the invented fire-resistant elements, for example of a door, the elastic part is encapsulated in the telescoping element and thereby protected against damage and environmental effects. The operational function of the telescoping element is consequently ensured over long periods of time and the effectiveness in the event of fire is retained.
The term building, as used in this text, includes walls comprised of known building materials such as building blocks and wood, as well as also walls, in particular partitioning walls, of glass.
In the following the invention will be explained in further detail in conjunction with embodiment examples with reference to the enclosed drawing. Therein depict:
telescoping element 31 in the direction of arrows 20 is thereby possible. Between the two parts 32 and 33 of telescoping element 31, again, a free interspace 19 is formed. In this interspace 19 is disposed an elastic part 21 which permits the movements of the second part 33 of telescoping element 31 in the direction of arrows 20. This elastic part 21 is comprised of the same materials as described with reference to
Depending on the construction and the fire safety requirements, the invented telescoping element 15 and 31 and 40, respectively, according to
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1457/04 | Sep 2004 | CH | national |
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PCT/CH2005/000507 | 8/30/2005 | WO | 00 | 4/3/2007 |
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WO2006/024187 | 3/9/2006 | WO | A |
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