RU2490290C2 - Fire-resistant coating - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to chemical industry and making fire-resistant and heat-insulating coatings. The fire-resistant coating contains liquid sodium glass as binder, coagulated liquid glass as granular filler and carbon nanoparticles that are dispersed in the binder and filler, with the following ratio of components, wt %: coagulated liquid glass - 12-50, carbon nanoparticles - 0.0001-0.1, liquid sodium glass - the balance.

EFFECT: invention improves heat-protective properties of the coating.

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Description

The invention relates to the chemical industry and relates to the creation of fire-resistant and insulating coatings.

Known fire retardant coating made in the form of a nanostructured material. The coating contains a porous skeleton formed by carbon nanostructures with metal atoms encapsulated in them, or metals with different physicochemical properties (RU No. 2366745, publ. September 10, 2009).

Known coating has high thermal efficiency and strength. The disadvantage is the high cost of coverage.

Known fire-resistant and heat-insulating coating, including liquid sodium or potassium glass as a binder and granular filler, which contains a mixture of hollow microspheres, varying in size from 10 to 500 microns and bulk density in the range from 650 to 50 kg / m ³ (RU No. 2288927, published on December 10, 2006). Hollow microspheres are selected from the group consisting of glass, ceramic, polymer, technogenic microspheres, or mixtures of microspheres are used. In a particular case, the coating contains liquid sodium glass - 4.5 wt.% And a mixture of hollow glass microspheres - 95.0 wt.%: Glass microspheres with a size of 35 μm and a density of 650 kg / m ³ - 40.0 wt.%, Glass microspheres with a size of 100 microns and a density of 150 kg / m ³ - 48.0 wt.%, glass microspheres with a size of 200 microns and a density of 70 kg / m ³ - 7.0 wt.%. Additionally contains a nonionic surfactant - 0.5 wt.%.

The use of mixtures of hollow microspheres reduces the density of the coating, increasing the efficiency of its heat-shielding properties. At the same time, special equipment is necessary for the production of various types of microspheres, which complicates the production technology and leads to a significant increase in the cost of coating.

The closest technical solution is a fire-retardant coating of compatible ingredients on a silicate basis, containing a binder - liquid sodium glass, granular filler - unburnt vermiculite, a heat-resistant additive - graphite in the form of dust-waste of carbon production, reinforcing filler - glass fiber, in the following ratio of components, wt .%: liquid sodium glass - 27 - 40; unburnt vermiculite - 25-35; specified graphite - 16-20; fiberglass - 15-18 (RU No. 2160296, publ. 10.12.2000). Due to the use of fiberglass as a reinforcing filler, this coating is quite durable. And graphite and vermiculite provide fire resistance and the thickness of the insulating layer. Using as a heat-resistant additive waste of coal production reduces the cost of flame retardant composition. Fire retardant coating has a fire resistance of 2.5-3 hours with a coating thickness of 45 mm.

A disadvantage of the known coating is a decrease in the efficiency of thermal protection due to the combustion of graphite at a temperature of 700 ° C.

The aim of the invention is to increase the efficiency of the heat-shielding properties of the coating without increasing its cost.

The purpose of the invention is achieved in that the fire-retardant coating comprising liquid sodium glass as a binder, a granular filler and a heat-resistant carbon additive contains coagulated liquid glass as a granular filler, and contains carbon nanoparticles dispersed in a binder and filler as a heat-resistant carbon additive. The ratio of the components of the coating is the following, wt.%:

coagulated liquid glass - 12-50,

carbon nanoparticles - 0.0001-0.1,

liquid sodium glass - the rest.

Unlike the prototype, where graphite in the coating burns at a temperature of 700 ° C, carbon nanoparticles placed inside the granules are protected from oxygen and begin to swell and burn after the destruction of the granules at temperatures above 1000 ° C. This allows you to increase the efficiency of the heat-shielding properties of the coating. Carbon nanoparticles are more active than graphite dust and, being dispersed into a binder and granular filler, form a carbon skeleton network in the coating, which increases the uniformity of the expansion of the coating in thickness, which positively affects the thermal conductivity of the coating and, therefore, fire resistance.

At the same time, the carbon mesh frame provides high coating strength.

The low concentration of nanoparticles in combination with inexpensive components made of liquid glass allows you to save a low coating cost.

When the concentration of nanoparticles is less than 0.0001%, the fire resistance of the coating does not increase. The concentration of nanoparticles in excess of 0.1% does not allow to obtain granules due to the high activity of the nanoparticles forming a film on the surface of the coagulant.

The concentration of granules in the base ranges from 12% to 50%, depending on the required degree of fire resistance. When the concentration of granules is less than 12%, the swelling of the coating is insufficient for fire protection of structures. When the concentration of granules is more than 50%, the adhesion of the coating with the protected material (wood, metal) is insufficient.

The figure shows a table of test results of the claimed flame retardant coating

To prepare the flame retardant, we used liquid sodium glass with a density ρ = 1.39 kg / m ³ with either Arkema Graphistrength ™ carbon nanotubes dispersed in its composition (Bordere S., Corpart JM, Bounia NE.E1, Gaillard P., Passade Boupat N., Piccione PM, Plee D. Industrial production and applications of carbon nanotubes / Arkema, Groupement de Recherches de Lacq, www.graphistrength.com), or with FULLERENCOM fullerenes (www.nanofull.ru), or CheapTubes graphenes (www. cheaptubes.com).

The preparation of the intumescent component was preliminarily performed by coagulation of liquid sodium glass in a medium of a solution of calcium chloride. When liquid glass sprayed with compressed air is introduced into a concentrated CaCl ₂ solution, due to the difference in pH of the solutions at the interface of the two liquid phases, the hydrolysis reaction proceeds the fastest. The neutralization of the charge of anions leads to their instantaneous coagulation at the interface, and if the concentration of silicates is high enough, a membrane is formed with a negative charge on the side of the silicate and positive on the side of the calcium chloride solution. At high viscosity of the silicate solution, the membrane gradually turns into a gel shell from coagulated silica with a small concentration gradient for calcium on the side of the CaCl ₂ solution and for sodium on the side of silicate [Korneev V.I., Danilov V.V. Soluble and liquid glass. - St. Petersburg: Stroyizdat, St. Petersburg, 1996. - 216 p.]. Moreover, under the influence of nanoparticles dispersed in liquid glass, coagulated silica is structured. After drying from external moisture, the formation of granules from liquid glass droplets with water resistance of the outer, partially calcined layer occurs.

The obtained granules were used to prepare a flame retardant in the form of a paste. Hardening of the paste applied to the surface of wood or metal protected from fire occurred under normal conditions.

Physico-mechanical characteristics of the material were evaluated by standard methods. Fire resistance tests were carried out in accordance with GOST 30247.0-94 (ISO 834-75). Construction structures. Test methods for fire resistance. General requirements.

The tests were carried out on steel and wood plates of 08 KP, GOST 16523-70 and dimensions of 140 × 80 mm with a thickness of 0.8 mm. At the same time, 50 g was spent per metal layer, and 60 g of material applied with a spatula to cover the wood.

Drying under natural conditions was checked according to GOST 19007-73, and adhesion was determined by testing the samples by the notch method (GOST 15140-78) with an Eicometer 1542. The coating lag in the area with transverse notches does not exceed 5%.

Using a gas burner, the fire retardant coating was heated. The flame temperature was 600 ° C.

The test results shown in the table showed the following: depending on the concentration of nanoparticles, the concentration of granules and the type of structure of nanoparticles (fullerenes, graphenes, nanotubes), the fire resistance of the coating on the metal ranges from 40 min - 150 min (REI 40 - REI 150), on wood from 25 min - 120 (REI 25 - REI 120), min with a coating thickness of 2-3 mm.

Thus, the claimed fire retardant coating on metal has a fire resistance of 150 min (REI 150) with a applied layer thickness of 2-3 mm, and in comparison with the prototype having fire resistance on a metal of 150-180 min at a coating thickness of 45 mm, has more effective heat-shielding properties .

Protected Material Coating thickness Nanotube concentration at pellet concentration 12% 12-50% fifty% 0.0001% 0.001% -0.1% 0.1% Wood 2-3 mm REI 60 REI 90-REI 120 REI 80 Metal 2-3 mm REI 80 REI 100-REI 150 REI 90 Protected Material Coating thickness The concentration of fullerenes at a concentration of granules 12% 12-50% fifty% 0.0001% 0.001% -0.1% 0.1% Wood 2-3 mm REI 30 REI 50 - REI 60 REI 40 Metal 2-3 mm REI 45 REI 70 - REI 80 REI 50 Protected Material Coating thickness The concentration of graphene at a concentration of granules 12% 12-50% fifty% 0.0001% 0.001% -0.1% 0.1% Wood 2-3 mm REI 25 REI 40 - REI 50 REI 30 Metal 2-3 mm REI 40 REI 50 - REI 60 REI 45

The fire resistance of building structures is set by the time (in minutes) the onset of one or several consecutive, normalized for this design, signs of limit states:

- loss of bearing capacity (R);

- loss of integrity (E);

- loss of insulating ability (I).

Claims (1)

Fire retardant coating, including liquid sodium glass as a binder, granular filler and heat-resistant carbon additive, characterized in that it contains coagulated liquid glass as a granular filler, and contains carbon nanoparticles dispersed in a binder and filler as a heat-resistant carbon additive, in the following ratio components, wt.%:
coagulated water glass 12-50 carbon nanoparticles 0.0001-0.1 liquid sodium glass rest