DE202004009680U1 - Structural component, especially ceiling or flexing beam in building, has for underside adhesive reinforcement a fireproof lining including at least 10mm thick insulating wool with melting point above 1,000 deg C - Google Patents

Abstract

The structural component (1) which is especially a ceiling or flexing beam in a building has at least underside adhesive reinforcement (4,5) covered at least one the underside by a fireproof lining which comprises at least 10mm thick insulating wool with a melting point above 1,000 deg C, and below this a cover (17) of class F120 fireproof plaster with a thickness of more than 20mm. The cover forms a flat closed cover surface, and the insulation (6) is connected to the component part independent of the cover.

Description

The The invention relates to a component, in particular a ceiling or a bending beam in a building with at least underside adhesive reinforcement, the covered at least on the underside by protective tape clothing is.

adhesive reinforcements for critical stressed components such as ceilings, beams or beams from different Materials become retroactive increase the resilience, especially the bending resilience, with adhesive reinforcement provided that in comparison to the attached suitable support structures are relatively simple and space-saving to install. Reinforced concrete structures with originally less applied load or with steel reinforcement attacked by corrosion can be amplified in an elegant way. Such reinforcement also comes in principle for steel structures, Wooden structures or stone structures. adhesive reinforcements Steel sheet now have significantly more fiber-reinforced plastics all carbon fiber reinforced Made room for plastics (CFRP). The carbon fibers or carbon fibers deliver very high tensile strength at low weight and also with high temperature resistance. However, the adhesive of the adhesive reinforcement poses when high temperatures and especially fire loads to be considered, a weak point The usual related epoxy resin glue fails at temperatures above 50 ° C and above 60 ° C.

Accordingly has already been tried with commercially available fire protection building boards, the surface of the adhesive reinforcement and possibly also covered on the side to produce fire protection clothing, which is the temperature at the adhesive reinforcement and thus the strength the component reinforcement via a predetermined time of flame exposure as guaranteed in the different Test methods is set. Such fire protection clothing is through trained specialist personnel to install and also takes up little space, so carries little under a blanket with adhesive reinforcement. For processing by non-specialized forces However, this fire protection clothing is not intended for use in construction.

task The invention is now a component with adhesive reinforcement and to create fire protection clothing, which also with existing ones Funds and working methods of specialist companies in the plastering and construction industry is to be produced without an excessive space requirement and big cost to claim, and which provides a surface acceptable for buildings, however, the adhesive reinforcement is reliable and effective against fire protects.

According to the invention this task of a component mach the generic term of the claim 1 based on the characterizing features of claim 1 solved.

Components with this fire protection clothing have proven themselves in the fire protection test according to the specified standard tests and kept a temperature of less than 50 ° C on the adhesive reinforcement, for example, for over ninety minutes when the test area was exposed to flame. The two-layer combination of fire protection clothing with insulation, which is covered by a sufficient layer of fire protection plaster, is obviously particularly suitable, on the one hand, to absorb the thermal stress and the associated thermal stresses on the surface or the outside, and on the other hand to protect the insulation underneath and thus the intercept high temperature differences. However, this includes materials that can withstand the stresses. In this regard, insulating wool, in particular mineral wool, with a melting point above 1,000 ° C and in non-flammable quality in accordance with fire protection class A1 must be provided. Mineral wool with a density of at least 150 kg / m ³ is expediently used. The fire protection plaster of fire protection class up to F120 is a mortar according to DIN classification P2 with a strength of more than 2.5 N / mm ² , which falls naturally into the area of light plasters and consists of a hydraulically binding, high-temperature-resistant binder compound. Such fire protection plaster is commercially available, for example, under the "Tendosit" brand.

The Cover is preferably designed as a closed cover surface, to also encapsulate the insulation on the edge. Both in terms of saving material as well as in terms of fire protection as well as in the sense of an appealing and easy to rework surface flat surfaces, especially as ceiling surfaces, to be preferable.

On embodiment the invention is illustrated in the drawing and is described below described in more detail. The only figure in the drawing shows a vertical section through the edge of a plate with adhesive reinforcement and fire protection clothing.

In the drawing is with 1 a component, namely a load-bearing reinforced concrete slab partially in an edge area with a right front edge in the drawing 2 shown. The vertical section shown represents a cross section through which run predominantly perpendicular to the plane of the drawing de component 1 that can be thought to the left. It is understood that a component as a bending beam also on the left side with one of the edge surfaces 2 corresponding edge area could be limited. The component could also be used as a ceiling, eliminating the edge surface 2 transition into a vertical load-bearing wall.

like Components need sometimes a subsequent one gain if they are higher than originally intended and charged should be charged, for example in the case of old ones Structures Deformations and dislocations have arisen from the subsurface are or if a steel reinforcement is insufficiently protected and is attacked by corrosion. Traditional reinforcements through additional supporting structures are complex, voluminous and often undesirable in terms of design. Be opposed in many cases Adhesive reinforcements made of sheet steel or fiber-reinforced plastic are used, especially increasingly made of carbon fiber reinforced plastic.

In the present case are on a lower surface of the component 1 that also with an adhesive layer 3 is provided as adhesive reinforcement 4 several strips of high-strength and pre-stretched carbon fiber material, each with an adhesive layer 5 attached in the form of an epoxy resin adhesive. It is easy to see that such reinforcement is extremely inexpensive and takes up little space. Reinforcements made of carbon fiber reinforced plastic or glass fiber reinforced plastic also have good corrosion protection.

In any case, however, there is a problem with glue in the case of components that must be designed to withstand a fire, which loses some of its grip from 50 ° C, in any case from 60 ° C and is therefore no longer able to withstand tensile forces from the loaded component 1 in the reinforcement 4 transferred to.

The adhesive reinforcement must be in accordance with the respective structural requirements, which means that in the event of a fire, component strength can be maintained for up to 120 minutes with a specified standard load 4 and especially their glue 5 be shielded against fire temperatures.

According to the invention, a multi-part fire protection clothing is provided, which first of all contains the adhesive reinforcement with insulation 6 from a high temperature resistant insulating wool, namely a mineral wool with a melting point above 1,000 ° C. This insulation preferably consists of a single layer, but, as shown in the present case, can also consist of two layers 7 . 8th of insulating wool panels that are interconnected by needling or other connections 9 . 10 . 11 are held together and their butt joints 12 . 13 are offset from each other. This insulation is made using glue dots 14 . 15 . 16 from a commercially available spatula adhesive directly on the component 1 attached.

The insulation 6 is covered by a cover 17 from a fire protection plaster of fire protection class F120, which also goes up around the insulation and the adhesive reinforcement along the front edge 2 is pulled up to shield fire from the side.

The strength of the insulation 6 and the strength of the cover 17 is to be made dependent on the fire protection requirement. From a minimum thickness of insulation 6 with 10 mm and a minimum thickness of the fire protection plaster 17 Starting with 20 mm, the thickness of the insulation is increased to over 20 mm and the fire protection plaster to over 30 mm, for example, for stronger and, in particular, longer fire loads. In any case, effective but compact, space-saving and structurally appropriate fire protection clothing can be achieved.

This fire protection clothing, which has already proven itself in tests, apparently benefits from the combination of different layers of clothing, in which the fire protection plaster mainly takes on the function of armor, while the less robust insulation for the required heat gradient to the component 1 and especially the adhesive layer 5 there.

The cover is useful 17 which, in any case, cannot be carried out over a large area by a plaster base 18 held and reinforced, also with an angled edge area 19 along the front edge 2 is pulled up. Plaster supports of a commercial type are made of metal such as structural steel and are lattice-shaped, that is to say provided with openings through which a sprayed-on or thrown-on plaster can penetrate in order to be firmly anchored after hardening. Here, lattice-shaped plaster supports can be designed in the form of fabrics, perforated sheets or expanded metals. Such plaster bases are appropriate by suitable, in particular metallic anchors 20 . 21 towards the component 1 to hang and anchor in this, for example, using metal dowels. It is understood that the anchorages 20 . 21 to the plaster base 18 can also be connected to horizontal girders, round bars and / or rails made of metal for flat bracing.

It is of particular interest that the cover is hung independently, not the Iso lation burdened and if necessary also leaves a gap to this, which is advantageous for thermal insulation.

The result is a component 1 , its adhesive reinforcement 4 not only withstands the required loads in terms of fire protection, but also with the cover 17 of fire protection plaster provides a visually appealing surface that is familiar to the construction specialists in terms of processing.

Claims (11)

Component ( 1 ), in particular the ceiling or bending beam in a building, with at least underside adhesive reinforcement ( 4 . 5 ), which is covered at least on the underside by fire protection clothing, characterized in that the fire protection clothing for adhesive reinforcement ( 4 . 5 ) towards at least 10 mm thick insulation ( 6 ) made of insulating wool with a melting point above 1,000 ° C and a cover underneath it ( 17 ) from fire protection plaster of fire protection class F120 with a thickness of more than 20 mm. Component ( 1 ) according to claim 1, characterized in that the cover ( 17 ) forms a flat, closed cover surface. Component ( 1 ) according to claim 1 or 2, characterized in that the insulation ( 6 ) regardless of the cover ( 17 ) with the component ( 1 ) connected is. Component ( 1 ) according to claim 3, characterized in that the insulation ( 6 ) at least punctiform with the component ( 1 ) is glued. Component ( 1 ) according to one of claims 1 to 4, characterized in that the insulation ( 6 ) in several layers ( 7 . 8th ) with between the layers ( 7 . 8th ) offset joints ( 12 . 13 ) is trained. Component ( 1 ) according to one of claims 1 to 5, characterized in that the cover ( 17 ) by a plaster base anchored in the component ( 18 ) is held. Component ( 1 ) according to claim 6, characterized in that the plaster base ( 18 ) consists of a metal grid. Component ( 1 ) according to claim 6 or 7, characterized in that the plaster base ( 18 ) compared to the component ( 1 ) through metallic anchors ( 20 . 21 ) is supported. Component ( 1 ) according to one of claims 1 to 8, characterized in that the insulation ( 6 ) is at least 12 mm thick. Component ( 1 ) according to claim 9, characterized in that the insulation ( 6 ) has a density of at least 150kg / m ³ . Component ( 1 ) according to one of claims 1 to 10, characterized in that the cover ( 17 ) with a fire protection plaster is at least 30mm thick.