RU150451U1 - COMPOSITION FIRE PROTECTION SYSTEM - Google Patents

Abstract

1. A composite fire retardant system, characterized in that it includes: (A) a metal element with a reduced thickness of not more than 5.8 mm, (B) an adhesive layer deposited on at least a portion of the surface of the said metal element; (C) heat insulating a plate made of basalt fiber and bonded to at least part of the surface of the metal element by means of an adhesive layer; (D) a layer of fire retardant coating applied to the surface of the entire structure. 2. The system according to claim 1, characterized in that the metal element has a shaped profile. The system according to claim 2, characterized in that the metal element has a profile in the form of an I-beam or channel, while the heat-insulating plate forms a cavity in the profile bounded by the internal surfaces of the profile and the heat-insulating plate. 4. The system according to claim 2, characterized in that the metal element has a profile in the form of a tee or corner, while the heat-insulating plate is connected by glue to the entire inner surface of the profile. The system according to claim 1, characterized in that the adhesive layer is made of glue based on liquid glass. The system according to p. 1, characterized in that it includes a layer of fire retardant coating containing acrylic or vinyl acetate copolymers, ammonium polyphosphate, polyols and melamine in the following ratio, mass. hours:

Description

The field of technology.

The utility model relates to the field of fire protection of metal products with a reduced thickness of less than 5.8 mm and can be used in industrial and civil engineering.

The prior art.

To calculate the thickness of fire retardant coatings and systems, the concept of “reduced metal thickness” is used.

The reduced metal thickness (δpr) is the ratio of the cross-sectional area of the metal structure S to the outer part of its perimeter P, which is subjected to fire:

δpr = S / P

The heated perimeter of the structure is determined in each case, depending on the method of installation, the profile of the structure, as well as the type of fire protection.

The fire resistance of an unprotected steel structure increases with an increase in its reduced thickness, and the greater the reduced thickness of a metal structure, the greater its fire resistance is in unprotected form, and the lower the cost of fire protection to ensure a given fire resistance limit.

Fireproof coatings are used to protect metal products.

When heated, the coatings begin to swell, creating a foam-coke coat with a low coefficient of thermal conductivity, which prevents the heating of a structure or product.

However, on metal products with a small reduced thickness [in the code of the Rules of SP 2.13130.2012, such thickness means a thickness of less than 5.8 mm) the use of such a paint is ineffective and is not allowed in accordance with these Rules.

In this regard, the issue of fire protection of metal structures with a small reduced thickness (less than 5.8 mm) becomes extremely relevant.

An obvious technical solution to improve the fire resistance of metal structures with a small reduced thickness is to increase this reduced thickness, which will make it possible to apply thin-layer fireproof coatings.

Currently, there are a number of technical solutions aimed at increasing the reduced thickness.

The source http / www.fireproof.ru / material / fire_barrier / id / 51 / (see the Appendix to application No. 1) discloses a composite fire-retardant system, including a steel corner or channel with a reduced thickness of less than 5.8 mm, filled with a fire-retardant solution based on expanded vermiculite, inorganic binder, fillers and targeted additives. A layer of fire-retardant paint is applied to the solution, a wire mesh is applied over the first layer, and additional layers of fire-retardant paint are applied to it.

This composite fire-retardant system is difficult to manufacture, requires a large number of material and unproductive time expenditures associated with layer-by-layer application of a solution based on expanded vermiculite. In addition, such a system can only be created if the metal element has a shaped profile (corner profile, channels, I-beams and others). If the metal element has a simple varietal profile (square, hexagon, strip of flat section), then it will be very difficult to create a composite system based on it because of the complexity of applying a solution based on vermiculite.

The closest analogue of the utility model is a composite fire retardant system, disclosed in the source http://www.yv-systems.ru/fireproof.htm (see Appendix to application No. 2).

This system includes a metal profile with a reduced thickness of less than 5.8 mm, a plate of expanded vermiculite fixed to the inside of the profile by means of self-tapping screws, and fire retardant paint applied to exposed parts of the metal profile.

In this fireproof system, the disadvantages of the first analogue have been partially eliminated and it has a fire resistance limit of 90 minutes.

The presence of self-tapping screws in a metal structure can serve as a source of stress concentrators, which can adversely affect the structural strength of the composite system. In addition, the presence of thermal bridges in the structure (metal screws) reduces the fire resistance of the known structure. Disclosure of a utility model.

The objective of the utility model is to eliminate all the inherent disadvantages of the prototype.

The problem is solved by a composite fire retardant system, including:

(A) a metal element with a reduced thickness of not more than 5.8 mm,

(B) an adhesive layer deposited on at least a portion of the surface of said metal element;

(C) a heat insulating plate made of basalt fiber and bonded to at least a part of the surface of the metal element by means of an adhesive layer;

D) a layer of fire retardant coating applied to the surface of the entire structure.

In private embodiments of the utility model, the problem is solved in that the metal element has a shaped profile.

If the metal element has a profile in the form of an I-beam or channel, then the heat-insulating plate can form a cavity in the profile limited by the internal surfaces of the profile and the heat-insulating plate.

If the metal element has a profile in the form of a tee or corner, then the heat-insulating plate can be bonded with glue to the entire inner surface of the profile.

The adhesive layer may be made of glue based on liquid glass. The system may include a layer of fire retardant coating containing acrylic or vinyl acetate copolymers, ammonium polyphosphate, polyols and melamine in the following ratio, mass, part:

ammonium polyphosphate 15-25 polyols 10-20 melamine 10-20 acrylic or vinyl acetate copolymers 5-20

The advantages of the proposed utility model are due to the fact that it contains a basalt fiber plate as a heat-insulating plate. Basalt fiber slabs have less thermal conductivity than expanded vermiculite slabs, therefore, they will more effectively prevent the spread of heat.

An advantage of the claimed system is also the use of glue for fixing basalt plates. On the one hand, this simplifies the manufacturing process of a fire-retardant system, and on the other hand, such a system does not form thermal bridges under operating conditions, since there are no self-tapping screws in the system, which positively affects fire resistance.

Implementation of a utility model.

In more detail, the features and advantages of the utility model are illustrated by drawings, in which the same positions are used to represent the same elements, and examples of implementation of the utility model.

A brief description of the drawings.

In FIG. 1 shows a schematic representation of a composite fire retardant system with a metal element in the form of a channel.

In FIG. 2 is a schematic representation of a composite fire retardant system with a metal element in the form of an I-beam.

In FIG. 3 shows a schematic representation of a composite fire retardant system with a metal element in the form of a Taurus.

In FIG. 4 is a schematic illustration of a composite fire retardant system with a metal element in the form of a corner.

Positions in the drawings mean the following.

1 ¹ - channel

1 ² - I-beam

1 ³ - brands

1 ⁴ - corner

2 - adhesive layer

3 - basalt plate

4 - layer of fireproof paint

5 - cavity bounded by the internal surfaces of the profile and plate

The utility model is implemented as follows.

On the prepared surface of the protected metal elements (1 ¹ , 1 ² , 1 ³ and 1 ⁴ ) (see Fig. 1-4), an adhesive layer (2) is applied, after which the heat-insulating plate (3) based on basalt fiber is installed. After the installation of the plate is carried out, a flame retardant is applied (4).

As glue any glue acceptable for these purposes can be used.

To reduce the cost of construction, glue based on liquid glass can be selected. If the viscosity of this glue is small and it will “move out” when applied, then you can add any thickeners (chalk, talc, kaolin, etc.) to it. In examples of the implementation of the utility model, an adhesive was used based on aqueous solutions of alkali metal silicates (water glass) and a thickener (kaolin - not more than 25 wt.%).

It should be noted that for metal elements having opposite shelves (channel (1 ¹ ) of Fig. 1 and I-beam (1 ² ) of Fig. 2), between which a plate (3) can be placed, it is advisable to apply a limited adhesive layer (2) on the edge of each shelf (see FIG. 1 and FIG. 2). In this case, the plate (3) is glued only to part of the shelf, forming a cavity (5) in the profile. Thus, not only the consumption of basalt plates and the consumption of glue are saved, but also the fire-retardant properties of the structure increase further.

For elements that do not have opposite shelves - Taurus (1 ³ ) and corner (1 ⁴ ), glue is applied to the entire surface in contact with the plate (3).

For the application of fire retardant coatings, any fire retardant paint can be used to protect the metal, however, it is best to use paints based on acrylic or vinyl acetate copolymers. Such paints may contain ammonium polyphosphates, polyols (for example, pentaerethritis, dextrin, starch, etc.), melamine and target additives and they are very widely represented in the prior art (see, for example, RU 2500703, RU 2492200, RU 2467041, RU 2011108709 and others). In this case, the copolymer can be used in the form of an aqueous dispersion, which is more typical for vinyl acetate copolymers, for example, PVA (polyvinyl acetate) or in the form of a solution of an acrylic polymer in an organic solvent.

In the example, paints forming a fire retardant coating of two compositions were used.

The first composition contained the following components, masses, parts:

ammonium polyphosphate 15-25 pentaerythritol 10-20 melamine 10-20 titanium dioxide 3-10 PVA water dispersion 15-20.

The second composition contained the following components, parts by weight:

ammonium polyphosphate 15-25 pentaerythritol 10-20 melamine 10-20 titanium dioxide 3-10 chloroparaffin 1-5

acrylic polymer solution

in organic solvent 30-50

Example.

The technological process of installation of the structural fire protection system of a metal element included the following steps:

- surface preparation of the metal element;

- application of an adhesive composition based on alkali metal silicates;

- installation of a basalt plate for insulation of metal structures;

- applying a flame retardant thermally expanding coating based on acrylic or vinyl acetate copolymers.

At the same time, on the channel (1) and the I-beam (1 ² ), an adhesive layer (2) was applied to a part of the shelf only at the contact point of the plate (3) with the channel or I-beam, as a result of which a cavity (5) was formed.

An adhesive layer was applied to the channel [1 ¹ ] and corner (1 ⁴ ) on the entire inner surface of the profiles and the contact of the plate (3) was made with the entire inner surface of these profiles. At the same time, a Taurus (1 ³ ) and a corner (1 ⁴ ) were coated with a fire-resistant coating containing the following components in mass, including: ammonium polyphosphate - 25, melamine - 10, pentaerythritol - 20, titanium dioxide - 3, polyvinyl acetate dispersion - 15 and for an I-beam (1 ² ) and a channel (1 ¹ ) ammonium polyphosphate - 15, melamine - 20, pentaerythritol - 10, titanium dioxide - 10, chlorine paraffin 5, a solution of an acrylic polymer in an organic solvent (xylene) - 50.

Next, tests of the fire resistance limit were carried out depending on the size of the profile of the metal element and its reduced thickness.

The test results are shown in table 1.

Claims (6)

1. Composite fire retardant system, characterized in that it includes: (A) a metal element with a reduced thickness of not more than 5.8 mm, (B) an adhesive layer deposited on at least a portion of the surface of said metal element; (C) a heat insulating plate made of basalt fiber and bonded to at least a part of the surface of the metal element by means of an adhesive layer; (D) a layer of fire retardant coating applied to the surface of the entire structure. 2. The system according to claim 1, characterized in that the metal element has a shaped profile. 3. The system according to claim 2, characterized in that the metal element has a profile in the form of an I-beam or channel, while the heat-insulating plate forms a cavity in the profile limited by the internal surfaces of the profile and the heat-insulating plate. 4. The system according to claim 2, characterized in that the metal element has a profile in the form of a tee or corner, while the heat-insulating plate is connected by glue to the entire inner surface of the profile. 5. The system according to claim 1, characterized in that the adhesive layer is made of glue based on liquid glass. 6. The system according to p. 1, characterized in that it includes a layer of fire retardant coating containing acrylic or vinyl acetate copolymers, ammonium polyphosphate, polyols and melamine in the following ratio, mass. hours: ammonium polyphosphate 15-25 polyols 10-20 melamine 10-20 titanium dioxide 3-10 acrylic or vinyl acetate copolymers 15-50

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