HU189683B - Mountable fire-protecting cover of combined lamellar structure advantageously for the protection against fire of steel structure of light-construction buildings - Google Patents

Abstract

FIELD OF THE INVENTION The present invention relates, in particular, to a light structure for fire protection of steel structures in buildings. The casing is an assembled laminated structure according to the invention, wherein the first layer is a fire protection sheet (4) known per se which is asbestos, swollen perlite. from a mixture of pumiéit and a cement binder material, the second layer of plasterboard (2) on which a third layer of metal mesh (6) is fixed and a fourth layer of plasterboard over the metal mesh (6). For higher fire resistance, the second layer of mineral fiber reinforced fire-retardant gypsum board (2). 21 20 Jl_ 23 ye * 22 ptb Figure 2 -1-

Description

(54) Mounted composite fire protection casing with composite layered structure, preferably for fire protection of steel structures in lightweight buildings (57)

FIELD OF THE INVENTION The present invention relates to a fire protection cover, preferably a lightweight structure for protecting a steel structure of buildings against fire.

The casing has an assembled laminate structure according to the invention, wherein the first layer is a self-contained fire protection shield (4) mounted on the steel structure, which is asbestos, expanded perlite. a second layer of gypsum board (2) on which is attached a third layer of metal mesh (6) and a fourth layer of gypsum board above the metal mesh (6).

For higher fire resistance requirements, a second layer of mineral fiber reinforced fire retardant plasterboard (2).

21 20 ji_ 23 you*

p feet

figure

189.683

FIELD OF THE INVENTION The present invention relates to a composite fire protection casing with a composite layered structure, preferably for the fire protection of steel structures in lightweight buildings.

Lightweight construction, with the steel frame as the load-bearing frame, is gaining increasing importance among modern building technologies.

Fire protection of steel structures must be ensured, as the strength properties of the steel structure deteriorate with increasing temperature, deformation occurs and the supporting structure loses its bearing capacity. The non-fire-resistant steel structure has only a very short fire resistance of about 15 minutes, so it is. fire protection of steel structures must be ensured.

In one known method of fire protection, the steel structure is coated with a known aromatic solvent protective paint. However, this solution is only suitable for low fire resistance requirements. Aside from the fact that the paint has a fire resistance time of only about an hour, the disadvantage of this method is that the application of paint requires a lengthy, labor-intensive effort.

According to another known solution, the steel structures are coated. The dispersed material may be, for example, a mixture of perlite, asbestos and silica water as a binder known as deaf. Another known blend used in practice comprises basalt wool, glass fiber, asbestos fiber, rice husk, rice straw fiber. Also known as ALBA-Τ is an epoxy-bonded, two-component solvent mixture. The asbestos fiber mixed with an inorganic binder is also spray applied. This type of diffused fire protection coatings has a very high fire resistance and a fire resistance time of 3 hours. However, their disadvantage is that spray coating is detrimental to workers' health and therefore the use of this method is prohibited for health reasons. However, proper health precautions make the procedure more expensive to the point where it becomes very uneconomic. A further disadvantage is that application by spraying results in high material loss. An additional cost factor to the above is the need to cover the spray coating with a separate coating.

Based on their fire resistance value, shields that are gjpszperlitet or so-called "shielding" are suitable. They are made of beaded concrete. Gypsum perlite molds have a fire resistance time of 1.5 hours. The polystyrene pearl bead contains a pearl fire resistance time of 3 hours. However, these shields have the disadvantage that the pre-fabricated moldings are knit in dimensions, so special attention must be paid to the shape of the shields when designing the steel structure. Another problem is that the space between the steel structure and the casing has to be molded with some material, which is a slow, cumbersome operation.

A similar type of solution is described in U.S. Patent No. 178983. The Hungarian patent specification, which describes a fire protection structure which is surrounded by a metal structure, is made up of at least two parts and can be mounted after installation. The elements made of polystyrene concrete are connected to each other in the form of grooves and secured to the supporting structure by means of an adhesive mortar. the aforementioned disadvantage, that is, the space between the element to be protected and the element providing fire protection.

No. 1,384,574. According to the British patent application for thermal insulation of supporting structures, the structural element to be insulated is surrounded by four insulating boards based on mica or pumica. The boards are covered with metal or decorative plates by gluing or screwing together. This solution was not designed specifically for fire protection purposes, but rather for thermal insulation purposes.

No. 1,959,387. The German Federal Publication Publication relates to composite sheet with good sound and heat insulation; however, like the previous solution, it is not primarily for fire protection purposes.

It is an object of the present invention to provide a fire protection casing which overcomes the drawbacks of the prior art, namely having a good fire resistance value, that is, not only for thermal insulation but also for fire protection, can be easily mounted on the steel structure and fit well with the steel structure. not harmful, can be made quickly, and the finished fire protection casing does not require the application of any additional casing.

The present invention is based on the discovery that our object can be achieved by a casing having a layered structure, which is different in layers, as opposed to prior art solutions which employ a single layer or possibly a decorative casing.

The layered casing according to the invention is spaced from the surface to be protected by spacers to form an insulating air layer. The innermost layer of the casing attached to the spacers is a fire protection plate known per se, consisting of a mixture of asbestos, expanded perlite, pumice and cement binder. However, this layer is absorbent, so plasterboard is used as a second layer surrounded by a third layer, a metal mesh. The outermost layer is again plasterboard, which may have the same appearance as the plasterboard wall surface. The laminate structure thus formed is virtually indestructible, and its installation technology is the same as the plasterboard installation technology known in the construction industry. The outer layer can be treated with the same surface treatment or coating as the plasterboard surfaces.

The fire protection casing according to the invention has a fire resistance time of 1.5 hours. The advantage of the solution is that the shielding panels forming the cover are easy to install, easily dimensioned by sawing and fastened, especially by screwing,

In a preferred embodiment of the fire protection casing according to the invention, which requires a higher fire resistance time, the second layer is made of mineral reinforced fire-retardant plasterboard. In this case, the needle resistance time is 2.5 hours, which is already very high.

In order that the fire protection cover can be easily mounted on the steel structure, steel sheet support profiles are fastened to the steel structure according to the invention, to which the first layer of fire protection shield and the second layer of gypsum board are screwed.

In a preferred embodiment, the metal mesh is galvanized wire mesh. This metal mesh may be provided, for example, with staples for the plasterboard of the second layer

189,683 recorded. The gypsum plasterboard of the fourth layer of the fire protection casing according to the invention is preferably fixed by means of adhesive plaster applied to the metal mesh. Appreciated by this action. that the outer surface of the gypsum board, which forms the outer surface of the protective sheet, remains intact, as there is no nailing or screwing, since the fixing is done by gluing.

The lower and upper edges of the fire protection casing according to the invention preferably fit into the ceiling or the floor by applying a layer of rock wool.

The fire protection cover according to the invention will now be described in more detail with reference to an exemplary embodiment shown in the drawings, wherein:

Figure 1 is a schematic view of a lightweight structure with a fire protection cover between floor and ceiling slab,

Fig. 2 is a sectional view A-A of the pillar of Fig. 1 and a

Figure 3 is a sectional view B-B of the pillar of Figure 1.

The structure of the fire protection casing according to the invention is illustrated in pillar 20 shown in FIG. The pillar 20 is between the ceiling 21 and the floor 22. The lower edge of the 20 pillars is surrounded by 23 concrete slabs. Figure 1 is a section plane A-A and section B-B, respectively, which are shown in Figure 2 and Figure 3, respectively.

Figure 2 illustrates the section A-A in more detail. As will be more clearly seen in Figure 3, the pillar 20 is formed by an I-holder. As shown in Fig. 2, the I-bracket core plate extends into the ceiling 21 and below the floor 22, and essentially the I-bracket is provided with layers of different materials that form the fire protection cover.

The fire protection shield 4 is placed directly on the base plate of the 1-holder. This fire protection sheet 4 consists of a mixture of asbestos, expanded perlite, pumice and cement binder. Such a fire protection shield is disclosed in U.S. Patent No. 180,328. Hungarian patent specification. The fire protection shield 4 mounted on the I-bracket 1 is supported by a bracket profile 3 made of galvanized sheet steel. This bracket profile 3 can be fastened to the I-bracket 1, for example, by nailing. A first layer of fire protection casing is attached to the support profile 3, which, like the layer below the support profile 3, is also a fire protection plate 4. This fire protection plate 4 is fastened to the support profile 3 by screwing, preferably by means of self-tapping steel screws.

The second layer consists of a gypsum board 2, which is also screwed to the support profile 3. The fire protection shield 4 of the first layer and the gypsum board 2 of the second layer can be screwed together to the support profile 3. The plasterboard 2 of the second layer is covered by a metal mesh 6 forming a third layer, which substantially increases the mechanical strength of the fire protection sheath. The metal mesh 6 can be fastened with a staple · to the plasterboard 2 of the second layer. Preferably, the metal mesh 6 is a galvanized wire braid that encircles the exemplary pillar 20.

The fourth and also the outermost layer of the fire protection shroud is again made of plasterboard 2 which, in addition to the fire protection effect, already forms the visible outer surface of the fire shroud. Accordingly, this outermost plasterboard 2 is glued to the previous layers. Bonding is done by means of adhesive plaster 7 applied to the metal mesh.

Figure 2 shows that the upper and lower edges of the fire protection casing according to the invention are connected via a layer of rock wool 9 to the floor 22 and to the ceiling 21 above. An insulating foil 10 is bent around the lower edge of the fire protection shroud towards the floor 22, on which exterior concrete 23 is laid. In this way, the lower edge of the fire shield is secured and insulated.

Figure 3 is essentially a sectional view B-B of the pillar 20. Figure 3 clearly shows that the 20 pillars are made up of the I-bracket. A fire protection plate is fastened to the belt plate at the top and bottom of the figure. In particular, it can be clearly seen in Fig. 3 that the support profiles 3 are substantially inverted U-profiles, of which the U-profile towards the waist plate is fixed to the waist by an angle shot and the opposite U-profile to the U-wedge profile. can be fixed by riveting. Of course, other profiles are also conceivable for attaching the fire protection casing to the steel structure.

Figure 3 shows how the I-holder 1 surrounds the fire protection shield 4, the plasterboard 2 the second layer, the metal mesh 6 which forms the third layer, and the gypsum board 2 which forms the outer layer. Fig. 3 shows that an edge protector 8 is provided at the corners of the fire protection cover, which serves partly to cover the meeting edges of the outer gypsum board 2 and partly to prevent mechanical damage.

The fire resistance of the fire protection casing thus formed is 1.5 hours. In the case where the gypsum plasterboard 2 constituting the second layer is made of a special fire protection gypsum plasterboard, which is reinforced with mineral fiber, such as DIN 18 180. standard, the fire protection limit of the fire shield increases to 2.5 hours. This fire resistance limit is already high enough to provide adequate protection for any steel structure.

The fire protection cover according to the invention is exemplified on a steel pillar. Of course, the same cover can be mounted on other steel structures. The gypsum plasterboard and fire protection panels that make up the individual layers can be cut to size during installation and can be screwed by nailing or gluing, ie relatively simple means. be dismantled without destruction.

Claims

Claims (2)

1. Mountable composite laminated fire protection casing, preferably lightweight building steel structure fire protection, characterized in that the inner layer of the composite laminated casing casing is asbestos, expanded perlite, a mixture of pumice and cement binder, a second known fire protection sheet (4). a layer of gypsum board (2) optionally containing mineral fiber reinforcement, to which a metal mesh (6) is fastened as a third layer and a gypsum board (2) is fastened as a fourth layer by means of adhesive gypsum, and the innermost layer of the laminate casing ) is fixed and the steel-37 An insulating air layer is formed between the support profile (3) of the plate 189,683 and the surface to be protected. Fire protection casing according to claim 1, characterized in that the second layer is a fire retardant plasterboard (2) containing mineral fiber reinforcement. 5. Fire protection cover according to one of claims 1 to 3, characterized in that the metal mesh (6) is fixed to the second layer of gypsum board (2) by means of staples. Fire protection cover according to claim 1 or 2, characterized in that the first (innermost layer) fire protection shield (4) and the second layer of gypsum board (2) are screwed to the steel sheet fastening profiles (3). 4. Fire protection casing according to any one of claims 1 to 3, characterized in that the metal mesh (6) is galvanized wire mesh. 6. Fire protection casing according to one of claims 1 to 3, characterized in that the plasterboard (2) of the fourth layer is fixed by means of adhesive plaster (7) applied to the metal mesh (6). 7. Fire protection casing according to any one of claims 1 to 3, characterized in that the upper and lower edges of the casing are joined to the ceiling (21) and the floor (22) by applying a layer of rock wool (9). 3 pieces of figure National Office of Invention Fk .: Zoltán Himer codex -4189.683 International Class Number: E 04 B 1/94 feet -5189 683 International Division Number: E 04 B 1/94 22 10 SECTION A-A Figure 2 -6189.683