RU2765373C2 - Method for heat protection of a fire bulkhead and fire-protective composition for coating planar structures - Google Patents

Abstract

FIELD: firefighting.

SUBSTANCE: invention relates to a method for creating a flame-protective coating on the surface of combustible and non-combustible materials. The method for heat protection of fire bulkheads consists in the fact that the bulkhead is equipped on at least one side with a multilayer fire-protective coating, is characterised by the fact that heat-insulating plates are used as a fire-protective coating, including a network of a non-combustible material and a powder made of natural mineral components, combined by a non-combustible and non-collapsible by bending and impact binder, wherein the heat-insulating plates, wherein a separating non-combustible fabric is placed between said plates, are secured on the bulkhead, and rigid non-combustible rolled products coated with a fire-protecting paint on the outside are used as an outer coating, wherein the network of a non-combustible material is made of asbestos threads, the powder made of natural mineral components has a heat capacity at least 5 times higher than the heat capacity of the sheet of rigid non-combustible rolled products and a heat conductivity at least 4 times lower than that of the non-combustible rolled products, a stainless steel sheet is used as rigid non-combustible rolled products.

EFFECT: duration of resistance to heat impact, reduction in the complexity of organisation of fire protection.

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Description

The invention relates to a method for creating a fire-retardant coating on the surface of combustible and non-combustible materials.

Known methods of fire protection, carried out by applying to the surface of the structure (material) of the product of a special composition [1-3]. In this case, a layer is formed on the surface that has the properties of a fire-retardant coating.

The fire-retardant effect of such coatings is based on the fact that at a certain temperature, which is lower than the ignition temperature of the protected material or the critical temperature of metal structures, spontaneous chemical reactions and physical processes begin, leading to the formation of foamed heat-insulating layers and (or) the release of phlegmatizing and inhibiting the combustion process. products. As a result, when exposed to flame and heat sources, the intensity of flame propagation decreases, and the fire resistance limit of structures increases.

Fire-retardant intumescent paints (compositions) are quite complex multicomponent systems. The essence of this method lies in the fact that the work on applying intumescent compositions to the surface of steel structures includes the following technological operations: surface preparation, preparation of the working composition of the coating, coating.

The significant disadvantages of this method are the following:

- over time, depending on the degree of environmental influence and other negative factors, protective coatings (treatments) lose their fire retardant properties, that is, they are subject to "aging", while the loss of fire retardant properties can take place without visible manifestations (the appearance of the coating practically does not change );

- the technological process of applying such coatings is complex, time-consuming and time-consuming: the formation of coatings takes up to 10 days

- the fire-retardant layer does not have the proper stability of properties, both in the thickness of the coating and in its area.

- fire-retardant layers have low resistance - on average from 0.75 to 1.5 hours at low temperatures - 140-200 degrees. WITH

A known method of obtaining a heat-insulating and fire-resistant multilayer combined polymer coating [4] (Patent RU, No. 2352601) This method includes the sequential application of top layers to a possibly preheated surface, first a liquid ceramic coating from a polymer composition containing a binder, a mixture of hollow microspheres that differ between themselves with sizes in the range from 10 to 500 microns and a bulk density from 650 to 50 kg/m ³ and auxiliary target additives, then one or more layers of fiberglass are applied to the resulting coating, if necessary, and then one or more layers of a polymer intumescent fire-resistant composition are applied with additives that provide an intumescent coating, and then the final drying of the coating is carried out. However, the resulting coating has a complex structure. Moreover, the hollow microspheres of this coating are used as a heat-insulating material, and the design of the microsphere itself is not adapted to placing in its core a substance that can significantly expand in volume when heated. The fire resistance of the coating is provided up to 3 hours, which is somewhat higher than in the previous cases, and the temperature difference during tests with heating is from 405 to 87 degrees. C on the outer layer of the coating.

The development of this method is the use in coatings of complex materials containing microcapsules with an extinguishing agent (water, in particular)

Known fire-extinguishing polymer composite material (OGKM) [5] (Reactive composite material for fire suppression systems. Patent RU No. 2161520). The material is not only passive, difficult to combust, but also reactive, which reacts to an increase in temperature or fire exposure by an immediate (inertialess) release of a powerful gasified fire extinguisher into the environment, which leads to a rapid (usually in several tens of seconds) fire suppression. OGKM is a polymer matrix filled with microcapsules containing a highly effective liquid fire extinguisher. By adjusting the composition of the matrix and the fire extinguisher, it is possible to control the temperature of the active reaction of the OGKM to external influences in the temperature range from 160°C to 230°C.

However, the main disadvantage of this material is that only by synchronizing the process of explosive destruction of microcapsules, accompanied by an intense release of fire extinguishing agent vapors, and its sufficiency for the destruction of the polymer matrix when the temperature rises due to fire exposure (directly or remotely), can the effect of powerful release of a fire extinguishing agent into the environment and, accordingly, suppression of the resulting combustion process.

If, under the conditions of fire impact on the OGKM, the polymer matrix melts, then the effect of "explosive" destruction of the material and a one-time release of fire extinguishing agent vapor into the fire zone will be lost, and if the matrix is too heat-resistant, then it (the matrix) will prevent the intensive release of the fire extinguishing agent for a long time. agent and the fire will have time to develop so much that the total amount of extinguishing agent will be insufficient for effective extinguishing.

Another disadvantage of this method is that the thermal effect on the object can be long, and the amount of extinguishing agents is finite, which only slows down the process of thermal action on the protected object.

Thus, from the above analogues it is clear that these methods of implementing fire-retardant coatings only slow down, for one time or another, the thermal effect on the object.

As a prototype, a method for obtaining a fire-retardant coating on the surface of combustible and non-combustible materials, a microencapsulated agent for creating a fire-retardant coating on the surface of combustible and non-combustible materials, a method for its production and a method for creating a fire-retardant intumescent coating [6] were selected.

In this method for obtaining a fire retardant coating on the surface of combustible and non-combustible materials, including preparing the surface, applying a first coating layer thereon, applying a second coating layer containing an intumescent substance thereon, and drying the coating, the second layer of the fire retardant coating being applied in the form of a matrix containing microencapsulated agent, the shell of which is filled with an intumescent substance, directly on the first layer of the coating before drying, and the drying of the coating is carried out at a temperature below the threshold at which spontaneous chemical reactions and physical processes begin in the intumescent substance enclosed in the core of the microcapsule, leading to the swelling of the substance ;

microencapsulated agent for creating a fire-retardant coating on the surface of combustible and non-combustible materials, which is a microcapsule, the shell of which is thermally destructible, and under normal conditions isolates the core from the external environment, is filled with an intumescent substance that, when heated, has the properties of a significant increase in volume with the formation of gas and vaporous substances that destroy the shell from the inside when it is heated;

a method for producing a microencapsulated agent for creating a fire-retardant coating on the surface of combustible and non-combustible materials, includes the formation of a microcapsule containing a single-layer spherical polymer thermally destructible shell and a core filled with an intumescent substance - paint or powder, which, when heated, has the properties of a significant increase in volume with the formation of gas - and vaporous substances that destroy the shell from the inside when it is heated;

a method for creating a fire-retardant intumescent coating, implemented by simultaneously heating the shell of the microcapsule and the substance enclosed in its core, followed by the destruction of the shell of the microcapsule, wherein the coating is created due to the volumetric expansion of the intumescent substance enclosed in the core of the microcapsule, when it is heated to a temperature at which the onset of spontaneous chemical reactions and physical processes, and the destruction of the microcapsule shell from the inside, with a uniform distribution on the surface of the intumescent substance - paint or powder.

Like previous analogues, the prototype has the same disadvantages - insufficient time of protection from thermal effects, uneven surface characteristics, reduction of fire-retardant parameters of the coating over time, significant technological complexity and laboriousness of coating formation.

However, in the field of protection of autonomous vehicles, there is an acute problem of increasing the time of the protective action of the coating in order to localize sources of ignition, protect the crew and minimize the consequences of fire.

The invention is based on the task of increasing the time of resistance to thermal effects, simplifying the formation of a protective surface layer, and manufacturing fire-retardant panels on an industrial basis.

The technical result - the duration of resistance to thermal effects, reducing the complexity of the organization of fire protection is ensured by the fact that:

- the bulkhead is equipped, at least on one side, with a multi-layer fire-retardant coating, characterized in that heat-insulating plates are used as a fire-retardant coating, including a network of non-combustible material and powder from natural mineral components, combined by a binder that is non-combustible and does not collapse during bending and impacts, with in this case, heat-insulating plates, between which a separating non-combustible fabric is placed, are fixed on the bulkhead, and rigid non-combustible rolled products coated on the outside with fire-retardant paint are used as an external coating;

- a network of non-combustible material is made of asbestos threads;

- powder from natural mineral components has a heat capacity of at least 5 times higher than the heat capacity of a sheet of rigid non-combustible rolled products, and thermal conductivity is not less than 4 times lower than that of non-combustible rolled products;

- a stainless steel sheet is used as a rigid non-combustible rolled product;

The following are examples of a specific implementation.

Example 1. When exposed to the same heat flux from a gas burner on a steel sheet with a clean surface and a steel sheet coated by the claimed method on the side opposite to the heat flow in the first case, after 2 minutes of exposure, the surface temperature of the clean sheet on the opposite side of the gas burner amounted to 368 degrees Celsius, and the surface temperature of the sheet coated with the claimed method - 54 degrees Celsius.

Example 2 When simulating the sudden and short-term thermal impact on the samples according to the previous example, the surface temperature of the bare sheet was 95 degrees Celsius, and the surface temperature of the sheet with the fireproof board was 31 degrees Celsius at an ambient temperature before testing of 23 degrees Celsius.

The given examples show that the claimed method allows to significantly reduce the level of thermal impact on protected objects and to increase several times the allowable duration of such exposure until irreversible changes in the partitions.

USED SOURCES OF INFORMATION.

1. Patent of the Russian Federation No. 2034816, 05/10/1995 Raw mixture for the manufacture of a fire-retardant coating.

2. RF patent No. 2249568, 04/10/2005. Fire-retardant composition "Firex-300" and fire-retardant barrier for cable penetrations "Shield-AK-3"

3. RF patent No. 2265631, 12/10/2005. Fire retardant coating.

4. RF patent No. 2352601, 04/20/2009. Method for producing a heat-insulating and fire-resistant multilayer combined polymer coating.

5. RF patent No. 2161520, 01/10/2001. Fire-extinguishing polymeric composite material.

6. RF patent No. 2580132 Method for producing a fire-retardant coating on the surface of combustible and non-combustible materials, a microencapsulated agent for creating a fire-retardant coating on the surface of combustible and non-combustible materials, a method for producing it and a method for creating a fire-retardant intumescent coating.

Claims (1)

A method for thermal protection of fire bulkheads, characterized in that the bulkhead is equipped on at least one side with a multi-layer fire retardant coating, characterized in that thermal insulation boards are used as a fire retardant coating, including a network of non-combustible material and powder from natural mineral components, combined by non-combustible and non-destructible when bending and hitting with a binder, while the heat-insulating plates, between which a separating non-combustible fabric is placed, are fixed on the bulkhead, and rigid non-combustible rolled products coated on the outside with fire-retardant paint are used as an external coating, while the network of non-combustible material is made of asbestos threads, powder from natural mineral components has a heat capacity of at least 5 times higher than the heat capacity of a sheet of rigid non-combustible rolled products, and a thermal conductivity of at least 4 times lower than that of non-combustible rolled products, stainless steel sheet is used as a rigid non-combustible rolled product. become.