RU2418139C2 - Fire protection lining - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: fire protection lining to coat walls and/or a ceiling (3) of reinforced concrete contains multiple fire protection elements (5) installed on the wall and/or ceiling. Between the fire protection elements (5) and the wall and/or the ceiling the spacer parts (7) are arranged, which hold the fire protection element (5) at the distance from the wall and/or the ceiling to form an air space between the fire-protection elements (5) and the wall and/or the ceiling. At the same time the fire-protection elements (5) are made as diffusion-open with provision of moisture suck-in at their one side and its transfer to the other side.

EFFECT: development of coating for walls and ceilings, providing reliable fire protection, and making it possible to prevent reinforcement corrosion.

7 cl, 3 dwg

Description

The invention relates to a fire wall cladding and / or reinforced concrete slab with a large number of tile fire elements installed on the wall and / or slab.

Fireproof linings of this type are used, for example, in tunnel pipes made of concrete, while concrete is reinforced with steel rods or a grill to increase the bearing capacity. Fire elements prevent cracking of concrete in case of fire and, therefore, exposure of supporting reinforcement. This, in particular, is especially relevant in case of failure of the reinforcing rods or lattice in case of fire and exceeding the critical temperature.

It was found that the built-in supporting reinforcement is susceptible to corrosion. This weakens the steel rods or grille. There is a danger that, due to the corrosion process, the support structure will fail over time.

The objective of the invention is to create a coating of walls and / or ceilings, providing reliable fire protection, on the one hand, and to prevent corrosion of the reinforcement, on the other.

To solve this problem, in the fire cladding for covering walls and / or ceilings of reinforced concrete, containing a large number of tile fire elements installed on the wall and / or ceilings, and spacers holding fire elements on the walls and / or ceilings are placed the distance from the wall and / or ceiling with the formation between the fire elements and the wall and / or ceiling of the air space, according to the invention, it is provided that against Fire elements are diffusion-open secured moisture absorption on one side of them and transmitting it on their other side.

Fire-fighting elements are made of material, which is a filter for substances in water that cause metal corrosion.

Fire elements are made of a material that is a filter for chloride contained in water.

Spacers are connected to fire elements.

Spacers are made of plastic.

Spacers are made in the form of tubercles.

Fire elements are screwed to the wall and / or ceiling, with at least some bolts passing through the respective spacers.

The invention takes into account the fact that, among other things, corrosion is caused by the chlorides present in the salts, in particular in the anti-icing salts that come with water to water the streets. This also applies to corrosive substances from exhaust gases from automobile engines. Chlorides penetrate concrete structures that do not have fire elements or through fire elements installed in the usual way, and thus come into contact with the reinforcement.

According to the invention, to minimize the penetration process described above, a spacer is provided which is combined with fire elements. Therefore, the fire elements are not laid directly on the (concrete) walls and / or floors, as was done before, but are installed at a distance from them. This measure further complicates the access of aggressive chlorides and other harmful substances to the wall and provides ventilation of fire-fighting elements, which prevents corrosion.

Preferably, at least one spacer is connected to the fire element. In the simplest case, it is about gluing. It is also possible to use more expensive bolted joints. Thus, the fire elements can already be provided with spacers at the place of manufacture and therefore are simply mounted on walls and / or floors.

It is advisable that the spacer was made of plastic, in particular rubber. Firstly, it gives the advantages of manufacturing technology; plastic spacers are easy to manufacture, for example, by injection molding. Secondly, the plastic material provides some flexibility. Therefore, even if the wall and / or floor to be cladding has irregularities, however, the fire plate according to the invention covers the wall and / or floor over the entire surface at a certain interval. It should also be pointed out that spacers can also be made of other corrosion-resistant materials.

The shape of the spacers can be optionally done in a wide range. Especially preferred was a shape made in the form of a tubercle. Individual tubercles with their outgoing flat side can be glued or screwed to the fire element. The top of the corresponding tubercle in the fixed position of the fire element is adjacent to the wall and / or ceiling.

Preferably, a layer of air remains between the respective tile fire element and the wall and / or ceiling. Ventilation of the fire element prevents the passage of chlorides and other corrosive substances. In this regard, it is proposed to distribute the spacers on the fire element in large quantities so that they create air space between these elements.

It is preferable that the fire element be made diffusively open, that is, made in such a way that, on the one hand, it sucks in water that is supplied to them through the other side. In this case, the material from which the fire element is made acts in the form of a filter of substances that can be in water and lead to metal corrosion, such as, for example, chlorides. In this regard, the fire element according to the invention can also be characterized as a “suction” fire element, which filters out substances that are in water, for example in street water, and which cause corrosion of metals and / or steel. In this regard, a fire element installed in front of a reinforced concrete wall and / or ceiling acts as a corrosion barrier.

The problem is also solved by the fact that between the fire element and the wall and / or floor spacers are installed that hold the fire elements at a distance from the wall and / or floor.

Until now, the regulations for inner tunnel shells and intermediate floors have required that the concrete cover of the supporting reinforcement be 60 mm for the moving space. In addition, a galvanized mesh reinforcement with its own concrete coating 20 mm thick could be provided in the concrete coating. The present invention provides a different solution. According to the invention, additional mesh reinforcement can be eliminated. In addition, the thickness of the concrete coating may be less than according to the prior art, that is, in the range between 40 and 60 mm.

Thus, it is possible to obtain a less expensive fire protection system for walls and / or ceilings made of reinforced concrete, consisting, firstly, of the fire cladding formed by the fire-fighting elements and, secondly, of the concrete coating of the supporting reinforcement. By creating a fire cladding and fixing it relative to the wall and / or floor, it is possible to reduce the thickness of the concrete coating, and you can also refuse to install additional reinforcement in the concrete coating. Therefore, the fire protection system consists of fire cladding and a less expensive and long-lasting concrete coating that successfully prevents corrosion of the reinforcement. At the same time, the fire protection system provides reliable protection of walls and / or floors, so that in case of fire there is no cracking of concrete, which can reach the reinforcement and lead to its significant weakening and, consequently, to the collapse of the tunnel.

Preferred embodiments of the invention are disclosed in the dependent claims.

Below the invention is explained in more detail using the drawings, including:

Figure 1 schematically depicts a cross-sectional view of a tunnel according to the invention;

Figure 2 - the traditional location of fire plates on the tunnel wall; and

Figure 3 is a sectional view of a fire element according to the invention in an assembly.

1 shows a sectional tunnel. The drawing shows the cross section of the tunnel 1, the roadway 2 and concrete walls and / or floors 3. Inside the concrete walls 3, reinforcement 4 is installed.

The reinforcement 4 increases the bearing capacity of concrete walls or floors 3. It may consist, for example, of steel rods or gratings.

As shown with a notch in FIG. 2, tile fire elements 5 are installed on the concrete wall and / or floor 3. They protect the concrete and, in particular, the reinforcement 4 placed inside in case of fire. It is known that the high temperature arising in the event of a fire due to the insecurity of tunnel walls and / or ceilings can lead to cracking of concrete up to exposure of reinforcement 4, as a result of which the latter may be damaged and may lose its protective function. In an extreme case, this can lead to a collapse of the tunnel.

Typically, fire plates are laid directly on concrete walls and / or floors, as shown in FIG. 2 by bolt connection 6. However, this can cause chlorides from salts or other corrosive substances to penetrate the concrete wall through the fire panels 5 and destroy valves 4. To optimize corrosion protection in the proposed embodiment, a large number of spacers 7 are installed on the corresponding fire protection element, one of which is shown in section in FIG. 3.

Preferably, the spacer 7 is made in the form of a tubercle, while its outgoing ends 8 are glued to the fire element 5. With its vertex 9, the tubercle abuts against a concrete wall and / or ceiling 3.

Due to this design, a gap 10 is created between the fire element 5 and the concrete wall and / or floor 3, which prevents the passage of chlorides and other aggressive substances into the concrete wall and / or floor. Interval 10 also provides ventilation for the fire element 5.

Figure 3 shows only one spacer 7. It is obvious that several spacers can be installed on the fire element. Through the spacer, the fire element 5 is connected to a concrete wall by means of a bolt or key connection 11. Corresponding spacers 7 can also be pre-mounted with bolts 11 on the fire element 5, so that in this case gluing or another type of fastening can be dispensed with.

The list of items in the drawing

1. The cross section of the tunnel

2. Roadway lane

3. Concrete wall and / or floor

4. Fittings

5. Fire element

6. Bolt / key connection

7. Spacer

8. Spacer ends

9. Spacer top

10. Interval

11. Bolt / key connection

Claims (7)

1. Fire cladding for coating walls and / or floors (3) made of reinforced concrete (4), containing a large number of tile fire elements installed on the wall and / or floors (5), between the fire elements (5) and the wall and / or spacers (7) are placed by overlapping, which hold the fire element (5) at a distance from the wall and / or overlap with the formation between the fire elements (5) and the wall and / or air space ceiling, characterized in that the fire elements (5) are made They are diffusion-open with the absorption of moisture on one side and transferring it to their other side. 2. Fire lining according to claim 1, characterized in that the fire elements (5) are made of a material that is a filter for substances in the water and causing corrosion of the metal. 3. Fire cladding according to claim 1 or 2, characterized in that the fire elements (5) are made of a material that is a filter for chloride contained in water. 4. Fire cladding according to claim 1, characterized in that the spacers (7) are connected to the fire elements (5). 5. Fire cladding according to claim 1, characterized in that the spacers (7) are made of plastic. 6. Fire cladding according to claim 1 or 5, characterized in that the spacers (7) are made in the form of tubercles. 7. Fire cladding according to claim 1, characterized in that the fire elements (5) are screwed to the wall and / or ceiling, while at least some of the bolts pass through the corresponding spacers (7).

Images