RU2342964C1 - Composite fire protection (versions) - Google Patents

Abstract

FIELD: security facilities.

SUBSTANCE: according to the first version the proposed sandwich fire protective structure based on composite plates can be fixed on the surface of the facility being protected and comprises low-density basalt-fibrous material layer, adhesive interlayer and heat-resistant protective-decorative plate which are sequentially adjacent to the above surface. Thicknesses and materials of the structure layers are chosen so that to provide for evaporation of water containing in the outer layer and adhesive interlayer, diffusion of the produced water vapour into the inner basalt-fibrous layer and under further heating evaporation of moisture condensed on the fibres surface, in case of fire attack or non-stationary heating of the structure outer layer surface. According to the second version the proposed sandwich fire protective structure can be fixed on the surface of the facility being protected with an air gap. The adhesive interlayer is made from heat-expanding material which is characterised by sooting when heated. Thicknesses and materials of the structure layers in this version are chosen so that to provide for precipitation of carbon particles on the inner layer fibres surface resulting from cracking of hydrocarbons which are included into the composition of the products of thermal decomposition of the adhesive interlayer organic or polymer part and for formation of an additional layer of foam coke resulting from thermal decomposition and swelling of the adhesive interlayer containing thermally expanding graphite, in case of fire attack or non-stationary heating of the structure outer layer surface . Fire protective structure layers are made with the consideration of physical effects appearing under heating and leading to the alteration of the adjacent layers composition; this fact allows blocking of radiant-convection heat flow coming from the flame to the surface of the facility being protected.

EFFECT: increasing up to the specified level fire resistance ratings of supporting and enveloping building structures primarily in high-rise buildings.

6 cl, 3 dwg

Description

The invention relates to fire-retardant fire fighting means and can be used to increase the fire resistance of load-bearing and enclosing building structures to a predetermined level, especially in high-rise buildings.

Higher fire resistance requirements are imposed on building structures and engineering communications of modern buildings and structures - the ability to maintain their load-bearing and enclosing ability under fire for a predetermined time necessary to take measures to evacuate people, actively counteract the spread of fire and its elimination.

So, for example, according to MGSN 4.19-05 "Multifunctional high-rise buildings and complexes" building structures of high-rise buildings must have a fire resistance limit of at least 4 hours.

With the fire impact on the building structures of high-rise buildings, their destruction (loss of fire resistance) is possible, accompanied by progressive destruction of the entire building (even if only structures within one of the rooms or floors are exposed to fire). As a result, the loss of fire resistance of high-rise buildings in a fire leads to much more serious consequences compared to conventional buildings.

To increase the actual fire resistance limits of building structures to the required level, fire protection is used.

The following requirements apply to fire protection of building structures and engineering communications elements:

a) low mass;

b) minimum cost;

c) the manufacturability of manufacture and installation at the facility;

d) resistance to external influences during installation and operation (accidental shocks, fluctuations in temperature and humidity of the atmosphere, etc.);

d) the absence of toxic secretions during operation, as well as bacteriological, allergic and endocrinological effects on people;

e) a sufficient warranty period;

g) the possibility of replacement and restoration depending on operating conditions;

h) the availability of appropriate protective and decorative qualities.

The first of these basic requirements in the case of high-rise buildings, for obvious reasons, becomes decisive.

A collapsible protective structure and a method for storing tanks with flammable substances are accepted as the closest (application RU No. 2004134118, publ. 10.05.2006).

The collapsible fireproof structure for storing tanks with flammable substances contains a supporting frame, a heat-resistant heat-insulating layer and a protective and decorative lining. In this case, the supporting frame consists of longitudinal and ring elements and is closed by cables connected to the pole rings. The heat-resistant heat-insulating layer is made in the form of flat mats fixed in the frame, made by sewing technology. It consists of outer woven layers, on the surface of one of which, facing the fire effect, a layer of intumescent material is applied, and an intermediate heat-resistant layer.

A characteristic feature of this known method is that in the structural composite fire protection there is a gap between the outer protective and decorative lining and the inner heat-resistant heat-insulating layer. And in a fire, this gap is filled with foam coke intumescent coating deposited on the surface of a heat-resistant heat-insulating layer. The outer lining protects the foam coke, which is an ideal high-temperature heat insulator, from burnout and shedding during prolonged fire exposure. Due to the successful combination of the properties of the individual layers of this composition, it is possible to significantly increase its effectiveness.

However, this collapsible fireproof design is not intended for use in buildings and structures due to the obvious complexity of manufacturing and the complexity of installation at the facility, leading to increased cost, especially with large areas of the protected surface, characteristic of modern high-rise buildings, underground structures and multifunctional complexes.

A technical solution is known (US 4351870 dated 09/28/1982), which discloses a protective panel having both a decorative and a structural function, which according to this invention can be used to protect high-rise buildings. This known fire-retardant construction consists of several layers superimposed on each other and has a large amplitude of the ratio of tensile strength to mass due to the use of light heat-insulating layers.

However, the disadvantage of this solution is the insufficient fire resistance limit in time due to the fact that it does not provide for the possibility of using physically changing properties of the layer materials and mutual influence for prolonged fire exposure to enhance the structure resistance.

Thus, the main technical objective of the proposed invention, as well as the technical result achieved, is the implementation of layers of a fire-retardant structure, taking into account the physical effects that occur when heated, leading to a change in the composition of the adjacent layers, which allows you to block the radiant-convective heat flux coming from the flame to the surface of the protected object .

According to the first embodiment of the invention, the indicated technical result is achieved in a layered fire-retardant construction based on composite plates, made with the possibility of fixing on the surface of the protected object and sequentially containing a layer of low-density basalt fiber material adjacent to the indicated surface, an adhesive layer and a heat-resistant protective and decorative plate, while the thickness and materials of the layers of the structure are selected from the condition that under fire exposure or unsteady ogreve its outer surface layer occurred evaporation of water contained in the material of the outer layer and the adhesive interlayer diffusion of water vapor formed in the inner layer of basalt and further heating the evaporation of moisture condensed on the surface of the fibers.

Preferably, a mineral-based composition is used as an adhesive layer, for example, a modified Conlit Glue silicate adhesive manufactured by Rockwool.

In addition, preferably, as a heat-resistant protective and decorative plate, a heat-resistant cement-based fire-retardant board with a filler of vermiculite or perlite and a reinforcing additive made from chopped basalt fiber, for example, Promatect plate, is used.

According to the second variant of the proposed invention, the technical result is achieved in a layered fire-retardant construction based on composite plates, made with the possibility of fixing on the surface of the protected object with the formation of an air gap and sequentially containing a layer of low-density basalt fiber material, an adhesive layer of thermally expanding material having the property of soot formation upon heating, and heat-resistant protective and decorative plate, while the thickness and materials of the layers of construction The selections are selected so that during fire exposure or unsteady heating of the surface of its outer layer, carbon particles precipitate on the surface of the fibers of the inner layer as a result of cracking of hydrocarbons that are part of the thermal decomposition products of the organic or polymer part of the adhesive layer and the formation of an additional foam coke layer due to thermal decomposition and swelling of the adhesive layer containing thermal expanding graphite.

Preferably, as the adhesive layer, an organic (polymer) -based composition is used, for example, containing thermally expanded graphite (TEG).

In addition, a Promatect cooker can also be used in this embodiment.

The proposed variants of the invention are united by the general idea of using materials emitted by the bonding layer when it is heated that penetrate the adjacent layer of low-density basalt fiber material to increase the fire-retardant ability of this layer and the entire structure as a whole.

Below, the proposed solution is disclosed in more detail with reference to the accompanying drawings, where Figures 1 and 2a, 2b show structural designs of these two fire retardant designs.

Figure 1 shows the first embodiment of the proposed invention, according to which a layered fire-retardant structure based on prefabricated composite plates made with the possibility of fixing on the surface of the protected object 1 (building structure or engineering communications) includes a layer 2 adjacent to the specified surface low-density cheap basalt fiber (mineral wool) material, adhesive layer 3 on a mineral basis and heat-resistant protective and decorative boards 4. Fastening layered fireproof structure to the protected object carried mechanical fastening elements 5.

In the first embodiment of the fire-retardant structure (Fig. 1), when water is exposed to the surface of its outer layer and unsteady heating, water evaporates, which is contained both in the material of this layer and (in larger quantities) in the adhesive layer. Water vapor diffuses into the inner basalt fiber composite fire retardant layer and condenses on the surface of the fibers. With further heating of the fire protection, condensed moisture evaporates. The consequence of these physical processes is a significant slowdown in the heating of composite fire protection: the so-called shelf (constant temperature section) is formed on the curve “temperature of the protected structure - time”.

Figure 2 shows a second embodiment of the proposed invention, according to which the layered fire-retardant structure is made on the basis of prefabricated composite plates, wherein Figure 2a shows the structure before fire exposure, and Figure 2b after fire exposure.

According to this embodiment, a layered fire-retardant structure made with the possibility of fixing on the surface of the protected object (building structure or engineering communication element) with the formation of an air gap B and sequentially containing a layer 2 of low-density cheap basalt fiber (mineral wool) material, an adhesive layer 3 of a thermally expanding material having the property soot formation during heating, and heat-resistant protective and decorative plate 4. Mounting a layered fire-retardant construction tion to the protected object and is carried mechanical fastening elements 5.

During the operation of composite fire protection according to the second embodiment (see Fig. 2a), the following favorable physical effects appear:

- deposition of carbon particles (soot) on the surface of the fibers of the inner layer as a result of cracking of hydrocarbons that are part of the thermal decomposition products of the organic (polymer) part of the adhesive layer;

- the formation of an additional layer of foam coke due to thermal decomposition and expansion of the adhesive layer containing thermally expanded graphite TRG.

The first of these physical effects leads to an increase in the absorption capacity of the inner basalt fiber composite fire protection layer and, accordingly, to a decrease in its thermal conductivity at elevated temperatures.

The formation of the foam coke layer (second physical effect) is accompanied by an increase in the total thickness of the fire-retardant structure (Fig.2b), which leads to a significant increase in the heat-insulating ability of the composition, since the foam coke has sufficient heat resistance and reduced heat conductivity at high temperatures.

At the same time, the outer heat-resistant layer of composite fire protection made of a material based on a mineral base prevents burnout and mechanical destruction of the foam coke under the influence of turbulent pulsations of the flame.

It should be noted that in the case of a long duration of fire exposure (up to 4 hours) according to standard temperature conditions, the surface of the fire-retardant structure is exposed to high temperatures (up to 1100 ° C). This requires the material of the subsurface layer of increased heat resistance. At the same time, the use of heat-resistant steels for the outer protective and decorative layer in the case of objects of the type under consideration is not practical for obvious reasons.

Most of the above requirements are met by heat-resistant fire-retardant boards based on special cement with vermiculite or perlite filler and hardening additive made from chopped basalt fiber, for example, Promatect boards. They have sufficient heat resistance, i.e. they retain their strength and initial shape when heated to temperatures characteristic of a developed fire, are resistant to the atmosphere during normal operation and have satisfactory protective and decorative qualities.

However, slabs of this type are relatively expensive and have a higher density. In addition, at high temperatures, their material transmits thermal radiation, which is the reason for its increased thermal conductivity and leads to the need for an unjustified increase in the thickness of fire protection from these plates with a long duration of fire exposure (increased requirements for the fire resistance of protected structures). Therefore, the use of slabs of this type becomes impractical for the fire protection of structures, which are subject to increased fire resistance requirements (up to 4 hours), and especially when there is a restriction on the mass of structures (for example, in the case of high-rise buildings).

Obtaining fire protection of minimum weight and cost under these conditions is possible by using a layered composition, the outer layer of which is heat-resistant boards of the Promatect type, and the inside is low-density and relatively cheap basalt fiber boards, for example PNTB, Rockwool Conlit, Paroc, etc., which have this good heat-insulating ability in the temperature range from 20 to 700 ° C (at temperatures exceeding 700 ° C, plates of this type begin to experience significant shrinkage, which dramatically reduces their fire retardant ability).

To connect the plates of the outer and inner layer between themselves, it is advisable to use two types of adhesive or bonding layers:

a) mineral-based compounds of the type of modified Conlit Glue silicate glue - for the first design option;

b) compositions on an organic (polymer) basis, containing thermally expanded (thermal expanding) graphite TRG - for the second design option.

Experimental studies have shown that with the correct choice of the thickness of these adhesive layers during the operation of this fire-retardant structure, additional physical effects appear that increase its fire-retardant ability.

Composite fire protection is fastened using standard fasteners, worked out with respect to fire protection with Promatect type plates (Promatect boards are mechanically attached to the protected structure, and basalt fiber boards of the inner layer are connected with an adhesive layer). Moreover, in the case of the composition of the second embodiment, its mechanical fastening to the structure is carried out taking into account the possibility of free sliding of the plates of the inner layer along the fasteners during the expansion of the adhesive layer. The fastening of composite fire protection to the protected structure in this case is made with a gap that is filled with flame retardant material during the construction process.

Thus, the implementation of the described physical effects leads to a significant increase in the flame retardant ability of composite fire protection. Calculations showed that in this case, the total thickness of the composite fire protection is less than the thickness of a single-layer fire-retardant material made of Promatect-type boards or basalt fiber boards.

The decrease in the composition of composite fire protection of the thickness of the outer layer of a relatively expensive material of high density can significantly reduce its cost and weight compared with fire protection from plates of this type alone.

It is important to emphasize that the optimal ratio between the layer thicknesses of the proposed composite fire protection is determined as a result of numerical calculations using the mathematical model proposed in the patent RU No. 2284202 owned by the applicant, the contents of which are fully incorporated here by reference. Only if the specified optimal ratio is obtained, it is possible to satisfy the requirements for fire protection of building structures listed at the beginning of the description in their entirety, this is possible using the mathematical model according to this patent. The method disclosed in it consists in forming a layered composite fire protection covering the protected object and determining its optimal composition and structure due to the adequate nature of the mathematical modeling of heat and mass transfer processes occurring in the fire protection and the protected object under fire exposure of varying intensity and duration.

Thus, the ratio between the thicknesses of the proposed fire-retardant construction for the first option: δ: δ ₁ : δ ₂ and for the second option: δ ₁ : δ ₂ : δ ₃ can be obtained by optimization calculation. In the case of the second embodiment, the thickness δ of the outer expensive Promatect layer is preferably selected in the range of 8-10 mm.

The proposed design of composite fire protection makes it possible to organize the industrial production of composite fireproof panels in the factory. Moreover, the means of this fire protection can be manufactured in the factory in the form of plates suitable for convenient installation on protected structures using standard fasteners. This reduces the complexity of installing fire protection at the facility compared to known solutions.

Claims (6)

1. A layered fire-retardant construction based on composite plates, made with the possibility of fixing on the surface of the protected object and sequentially containing a layer of low-density basalt fiber material adjacent to the indicated surface, an adhesive layer and a heat-resistant protective and decorative plate, while the thicknesses and materials of the structural layers are selected from the condition in case of fire exposure or unsteady heating of the surface of its outer layer, evaporation of water contained in the material externally layer and the adhesive layer, diffusion of the resulting water vapor into the inner basalt fiber layer and with further heating, evaporation of moisture condensed on the surface of the fibers. 2. The fire-retardant construction according to claim 1, in which a mineral-based composition is used as the adhesive layer, for example, Conlit Glue modified silicate adhesive. 3. The fire-retardant construction according to claim 1, in which a heat-resistant cement-based fire-retardant plate with a filler of vermiculite or perlite and a reinforcing additive of chopped basalt fiber, for example, Promatect plate, is used as a heat-resistant protective and decorative plate. 4. A layered fire-retardant design based on composite plates, made with the possibility of fixing on the surface of the protected object with the formation of an air gap and sequentially containing a layer of low-density basalt fiber material, an adhesive layer of heat-expanding material with the property of soot formation during heating, and a heat-resistant protective and decorative plate, with In this case, the thicknesses and materials of the layers of the structure are selected so that under fire exposure or unsteady heating NOSTA an outer layer occurred deposition of carbon particles on the surface of the inner layer of the fibers as a result of cracking of hydrocarbons from the products of thermal decomposition of an organic or polymer portion of the adhesive layer and the formation of an additional layer penokoksa due to thermal expansion and swelling of the adhesive layer containing thermally expandable graphite. 5. The fire-retardant construction according to claim 4, in which an organic (polymer) -based composition, for example, containing thermally expanded graphite (TEG), is used as an adhesive layer. 6. The fire-retardant construction according to claim 4, in which a heat-resistant cement-based fire-retardant slab is used as a heat-resistant protective and decorative slab with vermiculite or perlite filler and hardening additive made from chopped basalt fiber, for example, Promatect.

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