DE3110657A1 - Fire-resistant composite roof slab - Google Patents

Abstract

The invention relates to a non-combustible, multilayered roof slab, the upper cover layer of which comprises a profiled steel sheet and the lower cover layer of which is designed with a planar underside, the two layers being connected to one another in a shear-resistant manner by means of screws, via non-combustible webs consisting of high-temperature-insulating material. A mineral insulating layer is arranged between the webs such that an airgap is formed between them and the upper flanges of the upper profiled steel sheets. The cooperation of the lower cover layer, which is designed in a tension-resistant and compression-resistant manner owing to a possible continuous-beam effect, is achieved in the event of fire in that its upper part of the cross-sectional surface is high-temperature-insulated, with the result that, for example in the case of it being designed as a C-shaped steel sheet (Figure), its angled-off parts are embedded in the high-temperature-insulated webs or in the mineral insulating layer. Depending on dimensioning, such extremely lightweight composite slabs for standard loading achieve, as tests have shown, spans of from 4 m to 6 m and a fire-resistance duration of between approximately 30 and 120 minutes. <IMAGE>

Description

The invention relates to a multi-layer roof structure

made of an upper steel profile sheet and a lower tensile and pressure-resistant Top layer. The cover layers are shear-proof with each other through screws In the longitudinal and transverse direction running webs connected, which from a non-combustible and high temperature insulating material. The screws can be in larger Spaces are arranged if the cover layers with the webs are additionally temperature-resistant be glued. A core layer, which is heat-insulating, is arranged between the webs and is fire insulating.

In the previously known composite surface structures for roofs (e.g. OS 2011243 or P 2801966) the upper and lower cover layers are through non-combustible webs connected e.g. by sheet steel per file. But these don't work only as cold bridges, but also guide the fire temperatures quickly in the event of a fire in the upper cover plate, so that the collapse of the roof plate takes place before a fire resistance class can be achieved. For the version according to P 2700 416 is the disadvantage that the lower mineral fiber reinforced cover layer Must be kept moist over a long period of time to prevent flaking as a result of shrinkage stresses to avoid.

In addition, the rigidity and load-bearing capacity - like comparative tests shown raised - much less than with the lower sheet steel. A crucial one But the disadvantage is also that this roof plate is not used as a flow plate as the mineral fiber cement layer cannot absorb any compressive forces.

The two-component polyurethane can also be added to the cement / water Mixture complex and costly and an amount of up to eight percent by weight Addition of polyurethane too high to be classified in the non-combustible building material group A 1 of the DIN 4702 standard. After all, there is a dehydration of the moist, fresh perlite concrete only possible inside.

The object of the invention is to provide the two cover layers with high-temperature insulating To connect webs in a shear-proof manner even in the event of fire, so that they are also under fire temperature act statically as a composite system, which significantly increases the load-bearing capacity and rigidity not only at room temperature but also in the event of a fire compared to the load-bearing capacity the individual cross-sections is achieved.

The formation of the upper cover layer as a corrosion-protected steel profile sheet allows roof panels to be made in one piece from the ridge to the eaves while avoiding to produce combustible insulating material such as roofing felt or plastic sheeting. However, in the case of halls with a width of 20 m to 30 m, for example, this means that they are dimensioned as loudspeaker panels over one or two central purlins, whereby - as tests have shown - field widths 5 to 6 m ahead. However, the pass-through effect requires both the tensile strength as well as the pressure-resistant design of the lower cover layer.

This must be under the stress at room temperature for the load, this is the working load (Ci. a. dead weight + snow) multiplied by the The safety factor (generally 1.7 to 2.0 0) can be dimensioned.

The maintenance of the load-bearing capacity in the event of a fire is done according to the invention once through the formation of the lower cover layer as a fiber-reinforced silicate layer and choosing their thickness in the range between 10 mm and 25 mm, so that their tensile strength in the fields of the crease stiffness of the upper profiled steel sheet and its compressive stiffness above the purlins corresponds to the tensile strength of the upper profiled steel sheet.

As the temperature rises in the event of a fire, it falls although the strength of the outer, partial cross-sectional area facing the fire fiber-reinforced silicate layer, but its high-temperature insulating effect is retained. This protects thanks to the required compressive rigidity at room temperature the overall thickness selected to be sufficiently thick, the interior partial cross-sectional area, whose tensile strength and compressive stiffness enable the transfer of only 1.0 times the working load able to ensure at fire temperature. To achieve a high level of thermal insulation with simultaneous fire insulation of the upper fully load-bearing steel profile sheet mineral fiber felt mats are inserted between the bars. Another advantage is that the fire-insulating and load-transferring, tensile and compression-proof lower Top layer also makes a not insignificant contribution to thermal insulation at room temperature perform. To further improve the load transfer at fire temperature additional reinforcement, e.g. made of sheet steel strips, which are also profiled can be inserted between the webs and the lower cover layer.

The preservation of the load-bearing capacity in the event of a fire can according to the invention also by forming the lower cover layer from horizontally adjacent, C-shaped profiled steel sheets are made when choosing approximately the same sheet thickness like that of the upper steel profile cover layer. Then the tensile strength corresponds approximately of the lower steel sheets in the fields of the crease resistance of the upper steel profile sheet.

According to the invention, the compressive rigidity of the lower steel sheets by folding their edges to form webs and flanges of the same size that are connected to overlap the webs and flanges of the neighboring sheets, reaching the web height equal to the flange width equal to approx. 1/6 of the individual profile sheet width chosen so stiff Is that above the purlins the tensile strength of the top steel profile below the Load is reached. The lower sheets per file are made with high temperature permanent insulating concrete so that the beveled webs and flanges in embedded in the insulating concrete. In the event of fire, those protected by insulating concrete are sufficient Flarisc and the upper part of the webs are made to ensure the bond and work together with the upper steel profile sheet, 1.0 times the working load to achieve a Transfer fire resistance class. The training because of the type of construction Space between the air possible with bars enables the load-bearing elements to dry out Insulating concrete layer ouc months after production. The lower steel sheets also act as a vapor barrier.

In the case of training with a non-combustible insulation layer Insulating concrete becomes an essential one compared to the perlite concrete described in P 2700 416 Improvement is achieved when the mixture of insulating concrete is 100 parts by weight made of 30-70 percent by weight cement and 70-30 percent by weight inorganic lightweight aggregate consists of 80-120 percent by weight aqueous plastic dispersion and with the addition from 0.04 to 0.2 parts by weight of a water-soluble cellulose ether, set is. The inorganic lightweight aggregate can consist of perlite, vermiculite or otherwise an expanded mineral, the plastic dispersion consists of vinyl acetate, ethylene and vinyl chloride. With the help of these organic additives, which are usually only approx. make up one percent by weight of the dry weight of the insulating concrete, is a foam the cement matrix, whereby the bulk density of the insulating concrete is reduced from approx. 500 kg / m3 to approx. 300 to 400 kg / m3.

Surprisingly, this - as tests have shown - simultaneously the mechanical properties are decisively improved.

For example, with a bulk density of only 380 kg / m3 in comparison for insulating concrete without organic additives, the compressive strength and shear strength increased by approx. 300%, while the shrinkage is reduced to approx. 7/3. aside from that abrasion and adhesion are also significantly improved.

Figures 1 to 4 show embodiments of the invention and Figure 1 is a thermally insulated and fire-resistant composite surface structure consisting of the upper steel profile sheet cover layer 1, the lower fiber-reinforced silicate cover layer 2, which are connected to one another via webs made of fiber-reinforced silicate material 3 with screws 4 are connected.

Mineral fiber felt mats 5, 1 are inserted between the webs 3, which are insulated at the bottom with an aluminum foil 6 as a vapor barrier.

FIG. 2 shows a cross section with a ventilation space 7 between the steel profile sheet 1 and the mineral fiber felt mat 5, 1.

The self-grooving and with the help of a sealing washer 4, 1 sealing Screw 4 connects the steel profile sheet 1, the fiber-reinforced S; likat web 3 and the fiber-reinforced silicate cover layer 2 with one another. Between the undersides of the Strips 3 and the upper sides of the lower cover layer 2 are sheet steel strips 6 inserted.

In Figure 3 is an embodiment of a fire-resistant composite panel with transverse webs made of silicate 3, 1 between which the insulating layer 5, 2 is made Perlite concrete is introduced. The cover layer 1 consists of a steel trapezoidal sheet and the cover layer 2 made of a C-shaped folded sheet metal.

Figure 4 shows a cross section in which the screw 4 of the two Top layers can be seen.

Blank page

Claims (9)

Claims: I. Fire-resistant verb and roof panel with an upper profiled steel sheet and a lower non-combustible, tensile and pressure-resistant Top layer made up of non-combustible webs between which a mineral insulation layer is arranged, connected to each other in a shear-proof manner, are characterized in that The webs consist of a high temperature insulate the material that between the Upper chords of the steel profile sheet and. the mineral insulation layer is an intermediate air layer consists that the lower cover layer is flat on the underside and its Strength and stiffness values are just chosen so that they can be absorbed by it Tensile and compressive forces of both the crease and the tensile strength of the upper cover layer correspond, and that the upper part of the cross-sectional area of the the lower surface layer is highly temperature-insulated. 2. surface structures according to claim 1, characterized in that the Bars are arranged under each wave trough of the steel trapezoidal profile cover layer. 3. surface structures according to claim 1, characterized in that the Bars parallel to one another but transversely to the waves of the steel trapezoidal profile cover layer are arranged. 4. surface structures according to claim 1 to 2, characterized in that that the webs and the lower cover layer made of a fiber-reinforced silicate material exist. 5. surface supporting structures according to claim 1 to 3, characterized in that that the webs made of a fiber-reinforced silicate material and - the lower cover layer consist of adjacent C-shaped profiled steel sheets. 6. surface structures according to claim 1, 2 and 4, characterized in that that between the ribs mineral fiber felt mats, which in turn at least one-sided are coated with an aluminum foil, are arranged. 7. surface supporting structures according to claim 1 to 3 and 5, characterized in that that between the ribs a core layer of non-combustible insulating concrete with a Bulk density of 300-400tkgim3 is arranged, its mixture. at 100 parts by weight of 30-70 percent by weight cement and 70-30 Percentage by weight of a customary inorganic light additive consists of the 80-120 parts by weight of an aqueous plastic dispersion with a solids content from 1-10 percent by weight and with the addition of 0.04 to 0.2 parts by weight of one water-soluble cellulose ether is set. 8. Surface support structures according to claims 1, 2, 4 and characterized in that that a tensile reinforcement is arranged between the lower cover layer and the webs is. 9. Surface structures according to claim 1; 2, 4, 6 and 8, characterized in that that the tensile reinforcement consists of sheet steel strips the width of the webs.