RU2605988C1 - Composition for fire-retardant rubber coatings - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: invention relates to production of fire-retardant coatings based on polymer binder and can be used in rubber industry. Composition for fire-retardant coatings, which includes chlorosulphonated polyethylene, toluene and a modifier, modifier being dispersed carbon fibres.

EFFECT: high fire-retardant properties of coating and its adhesion to rubber.

1 cl, 2 tbl

Description

The invention relates to the field of production of flame retardant coatings based on a polymer binder and may find application in the rubber industry.

Known heat-protective coating containing a solution of chlorosulfonated polyethylene and stearic acid, granules of graphite, chemically oxidized, ammonium salts or borax, or boric acid, or antimony oxide, or mixtures thereof, magnesium oxide, zinc oxide and diphenylguanidine (Pat. RU 2210582, C09D 123 / 34, C09D 5/18; Published on 08.20.2003).

However, this heat-protective coating is not intended for fire protection of rubbers.

A known composition for heat-protective coatings, which includes an outer layer of chlorosulfonated polyethylene and at least one layer of a composition of liquid sodium glass hardener - sodium silicofluoride, filler - fireclay, aerosil and glass filaments 5-10 mm long, inorganic pigment and crystalline hydrates (Pat. RU 2162871, C09D 123/34, C09D 1/02, C09D 5/18; Published on 02/10/2001).

However, this composition does not have the necessary elasticity and has a complex composition.

A known composition based on chlorosulfonated polyethylene, including a filler, hardener and solvent, and additionally phosphorus-containing dimethacrylate (Pat. RU 2171269, C09D 123/34; Publ. 27.07.2001).

However, this composition is intended to produce hard coatings for floors and roofs.

Known fire retardant composition for combustible materials, which includes a solution of chlorosulfonated polyethylene in an organic solvent and liquid glass in the form of an aqueous solution of metal silicates or Quaternary ammonium (US Pat. RU 2202577, C09D 5/18, C09D 1/04, C09D 123/34; Publ. 04/20/2003).

However, this composition is intended for fire protection of wood.

A known composition for thermal barrier coatings containing chlorosulfonated polyethylene, toluene, thermally expanding graphite, zinc oxide, magnesium oxide, stearic acid, diphenylguanidine, ammonium phosphates and aluminum paste (Pat. RU 2186813, C09D 123/34; Publ. 10.08.2002).

However, this composition has a more complex formulation, which complicates its preparation.

The closest to the invention in technical essence is a composition for fire retardant coatings, including chlorosulfonated polyethylene, toluene, a phosphorus-containing compound, and as a phosphorus-containing compound, it contains a phosphorus-borazo-containing oligomer, previously obtained by the interaction of methyl phosphite borate, ED-20 epoxy resin and aniline (Pat. RU 2540645, C09D 123/34; publ. 02/10/2015).

However, this composition does not provide high fire protection and adhesion to rubber.

Objective: to obtain a composition based on chlorosulfonated polyethylene for fire retardant coating of rubbers with enhanced adhesion to rubbers.

The technical result is to increase the flame retardant properties of the coating and its adhesion to rubber.

The technical result is achieved in that the composition for fire retardant coatings, including chlorosulfonated polyethylene, toluene and a modifier, while as a modifier contains dispersed carbon fibers in the following ratio of components, parts by weight: chlorosulfonated polyethylene - 15.0, toluene - 85, 0, the specified carbon fiber is 0.1-0.5.

Chlorosulfonated polyethylene is the main film-forming in paint and varnish anticorrosive coatings (TU 6-55-9-90).

Toluene is an organic solvent (GOST 14710-78).

Carbon fibers are a fibrous material in the form of a dispersed powder with a color from dark gray to black. Weighted average length of about 200 microns. An aspect ratio of about 30. Strength 3.8-4 GPa. The modulus of elasticity is 230 GPa. Diameter 7 microns. Density 1.8 g / cm ³ . Actual humidity, mass. %, no more than 1.0.

The presence of dispersed carbon fibers as a modifier in the composition gives the coating on the basis of chlorosulfonated polyethylene fire resistance and increases its adhesive properties and heat resistance. An increase in the adhesive strength of bonding with rubber occurs due to an increase in the cohesive strength of the film of the coating itself, since when the adhesive compound is broken, the gap may be cohesive in nature (along the coating film). In addition, an increase in the adhesion strength of the coating to rubber occurs due to the effect of “mechanical jamming” of carbon fibers in the array of protected vulcanized rubbers.

This composition allows to obtain coatings based on chlorosulfonated polyethylene with increased fire protection and adhesion to vulcanized rubber.

The use of 15% solutions of chlorosulfonated polyethylene is most optimal. With increasing concentration, the viscosity of the solutions increases, which creates technological difficulties in the application of coatings and leads to a deterioration in the fire retardant properties of the coating.

The use of solutions of a lower concentration leads to an increase in the volume of compositions to obtain a coating of the required thickness. A decrease in the content of carbon fibers leads to a decrease in fire resistance and adhesion, and an increase in their content contributes to a decrease in adhesion to vulcanized rubber.

Fire retardant composition is prepared as follows.

First, a solution of chlorosulfonated polyethylene is prepared. Chlorosulfonated polyethylene and solvent - toluene are loaded into a flask with a stirrer and stirred for 4.5 hours until completely dissolved. Then the introduction of carbon fibers. The total cooking time is 5 hours.

The invention is illustrated by the following example.

Dispersed carbon fibers are introduced into a flask containing a solution of chlorosulfonated polyethylene in toluene and the contents are mixed for 3-5 minutes until a homogeneous mass is obtained.

For comparative tests, 3 variants of the compositions were prepared (by the method described in the example) and the composition of the prototype, the formulations of which are presented in table. one.

The composition is a beige liquid. It is well applied on a rubber surface.

The stated limits of carbon fibers are due to the fact that with an increase in these dosages, adhesion to vulcanized rubber decreases, and with a decrease, adhesion to vulcanized rubber decreases and fire protection decreases.

The properties of the coatings were studied at different contents of these carbon fibers. Comparative tests of the adhesion properties of coatings for all variants of the claimed composition and for example to vulcanized rubber based on nitrile butadiene rubber (SKN-18) and chloroprene rubber (Neoprene AC) and ethylene-propylene rubber (SKEPT-40) are given in table. 2.

The proposed coatings were tested for adhesive shear strength, achieved when kept under a load of 2 kg, at room temperature (20 ° C) for 24 hours. The data are presented in table 2, from which it can be seen that all coatings of the proposed composition in terms of fire retardant and adhesive characteristics exceed the fire retardant coating of the prototype, the best results were obtained using composition 2-3.

Adhesive shear strength was determined on an MPC-250 tensile testing machine (RTM 12126-88). The technology for bonding samples is as follows. One-time application of the prepared coating on the prepared surface, drying of the film at room temperature (20 ° C) for 1-2 minutes, after which the glued surfaces were pressed tightly.

The proposed coating provides a significant increase in the adhesion properties of vulcanized rubber compared with the control example.

In order to determine the effectiveness of the developed flame retardants, coatings were tested by exposing the treated specimen to vulcanized rubber to an open flame source. The test setup is assembled on the basis of a laboratory chemical tripod and installed in a well-ventilated room. Samples for measurements have the following dimensions: length - 50 mm, width - 50 mm, thickness - 1.8-2 mm. The thickness of the fire retardant coating is 1.0 mm. The claimed coating thickness is explained by the fact that with a decrease in the coating thickness the necessary fire retardant properties are not achieved, and an increase in the coating thickness leads to an increase in the curing time of the composition. Before measurements, coated samples are dried at room temperature for at least 24 hours.

Before measurements, the coated samples are dried at room temperature for at least two days. The sample prepared for testing is fixed vertically in a tripod. Use a universal gas burner Bunsen, equipped with a nozzle with a hole diameter of 7 mm. A gas burner (using household gas) located in a horizontal position at a distance of not less than 200 mm from the sample is ignited and adjusted so that the flame height is 150-180 mm. The flame is directed exactly to the center of the fixed sample of the vulcanizate. The air supply is regulated until the yellow tip of the flame disappears.

Temperature measurements are carried out by the device - S-300.3 pyrometer (GOST 28243-96 "Pyrometers. General technical requirements"). The principle of operation of the pyrometer is based on measuring the thermal radiation power of the measurement object mainly in the ranges of infrared radiation and visible light.

Using a pyrometer, a temperature change is recorded on the unheated surface of the test sample over time until the limit state of the test sample of the vulcanizate is reached. For the ultimate state of the material, the appearance of a burn on the unheated side of the prototype was taken - loss of integrity of the coating.

The results are shown in table. 2.

A study of resistance to fire shows that the introduction of dispersed carbon fibers into the composition as a modifier helps to ensure high fire resistance of the coating.

Thus, the introduction of dispersed carbon fibers into the composition for fire retardant coatings of rubber provides a high fire resistance of the coating and improves its adhesion to rubbers based on various rubbers.

Claims (2)

Composition for fire retardant coatings, including chlorosulfonated polyethylene, toluene and a modifier, characterized in that it contains dispersed carbon fibers as a modifier, in the following ratio, wt.h .: Chlorosulfonated Polyethylene 15.0 Toluene 85.0 Specified Carbon Fiber 0.1-0.5