RU2177973C2 - Fireproof foaming enamel - Google Patents

Abstract

FIELD: paintwork materials, more particularly coating of metallic, wood and other structures. SUBSTANCE: composition comprises chlorinated polyvinyl chloride derivative, organosilicon resin, pentaphthalic resin, polymeric phosphate resin, epoxy resin, low-molecular phosphate compound, oxidized graphite, pigment, solvent. EFFECT: improved fireproofness of structure up to 65 min, reduced smoke formation and increased heat resistance of enamel up to 700 C. 2 cl, 4 ex, 1 tbl

Description

 The invention relates to paints and varnishes, namely fire retardant enamels and can be used for coating metal, wood and other structures.

The known composition of fire-retardant enamel ("Organic coatings of reduced combustibility", L. N. Mashlyakovsky et al., 1989, Leningrad, ed. "Chemistry", p. 90), including a binder, plasticizers, acceptors, and a solvent, as a binder is used polyvinyl chloride, in the following ratio of components in wt. %:
Polyvinyl chloride - 40-45
Dioctyl phthalate - 15-20
P-tert-butylphenyl diphenyl phosphate - 5-7
Alumina Trihydrate - 24-27
Solvent - Else.

The disadvantage of the described fire-retardant enamel is its unsatisfactory heat resistance, decomposition of polyvinyl chloride at t ^o > 150-200 ^o C, despite the stabilizing additives. High smoke generation during decomposition of polyvinyl chloride, despite the addition of alumina trihydrate, which complicates fire fighting. In addition, a thin film quickly transfers heat, and fire protection with such a coating in duration does not exceed 1.5-2 minutes at temperatures up to 600 ^o C.

The closest to the claimed invention according to the achieved result is the composition of fire-retardant enamel ("Organic coatings of reduced combustibility", L. N. Mashlyakovsky and others, Leningrad, ed. "Chemistry", p. 90), including a binder, plasticizers, acceptors, intumescent additives, fillers, pigments and a solvent, polyvinyl chloride was used as a binder in the following ratio of components wt. %:
Polyvinyl chloride - 60-65
Dioctyl phthalate - 15-20
Epoxidized Soybean Oil - 2.5-3
Barite-cadmium stabilizer - 1.5-2
Tricresyl Phosphate - 8-10
Solvent - Else.

The disadvantage of the described composition of fire-retardant enamel is that when the temperature rises, polyvinyl chloride begins to decompose, which is accompanied by large smoke formation, which makes fire extinguishing difficult, and a thin coating film is only 1 mm and can withstand temperatures up to 600 ^o for 1.5-2 minutes.

 Thus, this flame retardant enamel does not have a high enough fire resistance, heavy smoke formation.

The basis of the invention is the task of obtaining flame retardant intumescent enamel with high heat resistance and small smoke with increasing temperature, the solution to this problem will allow to obtain enamel coatings for structures of various materials with reliable fire protection and high performance. The problem is solved in that in a fire retardant intumescent enamel, including a binder, plasticizers, acceptors, intumescent additives, pigments and a solvent, a mixture consisting of a chlorinated derivative of polyvinyl chloride, organosilicon compounds and pentaphthalic resin is used as a binder, epoxy is introduced as a plasticizer and acceptor resin, and as intumescent additives - low molecular weight and polymer phosphate compounds and oxidized graphite in the following ratio of components in, wt. %:
Chlorinated PVC derivative - 6.5-14.9
Organosilicon resin - 6.5-14.9
Pentaphthalic Resin - 1.95-4.3
Epoxy - 1.3-2.1
Low molecular weight phosphate compound, not less than - 13
Polymer phosphate compound, not less than - 13
Oxidized graphite, not less than 1.95
Pigment - 1.3-2.1
Solvent - Else.

 A comparative analysis of the inventive composition of flame retardant intumescent enamel with the prototype ("Organic coatings of reduced combustibility", L. N. Mashlyakovsky et al., 1989, Leningrad, ed. "Chemistry", p. 90), allows us to conclude that the claimed flame retardant intumescent enamel differs from the known use as a binder mixture of a chlorinated derivative of polyvinyl chloride, organosilicon and pentaphthalic resins, as intumescent additives - low molecular weight and polymeric phosphate compounds, oxidized gra fita, and as a plasticizer and acceptor - epoxy resin, which is sufficient for the formation of a strong flame retardant film and a decrease in smoke formation at higher temperatures and, therefore, to increase operational properties.

 Analysis of the known technical solution allows us to conclude that the claimed solution is not known from the prior art, which indicates its compliance with the criterion of "NEW".

The introduction of organosilicon compounds reduces smoke formation and increases heat resistance, because when the temperature rises above 500 ^o C, the organic part of the binder burns out, but the binder based on silicon remains. In addition, the combination of organosilicon resin and chlorinated polyvinyl chloride enhances the aesthetic appearance of the enamel film, since one chlorinated polyvinyl chloride is highly elastic and, when applied to the surface of the structure, the film of the required thickness (over 0.5-0.7 mm) “wrinkles”, the surface not made smooth.

The organosilicon resin proposed in the fire retardant enamel is declared without isolating the class of organosilicon compounds, because it is very important for the declared enamel that at a temperature of 600-800 ^o C and higher, silica remains from the compounds based on silanes, siloxanes and silazanes (the organic part " burns out "), which under the action of temperature forms a silica binder that binds and strengthens carbonized residues, making the heat-insulating layer reliable. The degree of polymerization, which distinguishes these compounds, structural and other differences, does not matter, since a silica binder is formed at high temperature from silicon atoms exposed to high temperature.

 The organic part of organosilicon compounds is degraded at a higher temperature than perchlorovinyl film-forming. However, perchlorovinyl film-forming is also important in this formulation, because it is the first to begin chemical transformations when exposed to temperature, taking a certain part of the heat to it and protecting the substrate.

Under normal conditions, the temperature is 20 ^o C, for the use of organosilicon compounds as the main film former certain conditions are necessary. In combination with perchlorovinyl resin, pentaphthalic, epoxy resins, organosilicon compounds form, under ordinary conditions, a solid, elastic, film with good adhesion.

 The pentaphthalic resin can be any, i.e., modified with various oils, phenol-formaldehyde, carbide, etc. resins, since the pentaerythritol oligomer formed during the depolymerization of pentaphthalic resin (breaking of ester bonds, sublimation of phthalic anhydride) is important for the claimed formulation necessary to form a valuable carbonized residue that does not support combustion and therefore protects the structure from flame.

Epoxy resin is an acceptor for hydrochloric acid (HCl), emitted in the form of smoke when decomposed from an elevated temperature to 500 ^° C of chlorinated polyvinyl chloride, thereby reducing smoke formation (the release of HCl into the atmosphere, in large quantities, is impractical).

 The content of active ions or ion groups in perchlorovinyl, organosilicon film formers causes intramolecular transformations that reduce the quality of the film formers.

Epoxy resins containing epoxy and hydroxyl groups, interacting with the active groups of perchlorovinyl and organosilicon film-forming, reduce the possibility of intramolecular transformations and, having a long and branched (high molecular weight compounds) chain, or branched structure (low molecular weight compounds), plasticize these film-forming. The epoxy group is in a stressed state, the ring tends to break, therefore it reacts quite easily with other active groups (for example, with H ⁺ , the reaction temperature is ~ 50 ^o С). The reaction proceeds when the film ripens to a certain extent and intensifies when heated to 50 ^o C and above (for example, sunlight).

 The epoxy and hydroxyl groups actively react with Hcl, i.e., the epoxy film-forming is an Hcl acceptor.

 In the 80s, diane epoxies accounted for 90% of the production of epoxies; 4% were epoxynovolacs and cycloaliphatic epoxies, 2% were accounted for by other types of epoxies. Until our time, these ratios have not changed significantly.

 For the formulation of the proposed enamel, the most significant are the available epoxy, and in particular hydroxyl groups, the amount of which varies depending on the type of epoxy resins, but this fluctuation does not exceed 15-20%. With the deficiency of certain types of resins, these fluctuations can be neglected.

 The introduced phosphate compounds and oxidized graphite, being both fillers and intumescent additives, significantly increase the fire protection of the material under the enamel coating, which alternately swells with increasing temperature.

At a temperature of 150-300 ^o C, a low molecular weight phosphate compound begins to decompose, then a phosphate polymer enters the reaction, decomposes at a temperature above 300 ^o C and the reaction continues to a temperature of 700 ^o C, and at a temperature above 550 ^o C oxidized graphite begins to swell. The resulting expanded fire-retardant film reaches a thickness of 30 mm. This is a non-shedding heat-insulating layer, the formation of which due to the transformations of film-forming agents and fillers under the influence of temperature, as well as subsequent heat-shielding actions last at least 60-65 minutes.

 In the claimed formulation of fire retardant intumescent enamel, various pigments are offered as pigments, for example, titanium dioxide, zinc oxide, yellow and red iron oxides, zinc yellow, lithopone, aluminum powder, etc.

 Soot occupies a special position, the methods of reducing the flammability of which we have worked out. Methods are being developed for modifying other organic pigments (which does not change color fastness), which excludes the flammability of pigments, which makes it possible to use them in fireproof intumescent enamels.

 As solvents for the preparation of fire retardant enamel, in particular, complex solvents of the R-5, R-646 type with the addition of white spirit and other solvents in small quantities are used. For perchlorovinyl, pentaphthalic, and organosilicon film-forming solvents they have a common basis - aromatic hydrocarbons that make up 50-60% of the mixture (toluene, xylene), therefore it is necessary to include aromatic hydrocarbons in the complex solvent, it is advisable to introduce, for example, ketones, which when dissolved are sharply reduce the viscosity of the film-forming, and other solvents mentioned above.

 The claimed composition of flame retardant intumescent enamel is shown in the table.

Claims (1)

Fire retardant intumescent enamel, including a binder, plasticizers, acceptors, pigment and solvent, characterized in that it contains a chlorinated derivative of polyvinyl chloride, an organosilicon and pentaphthalic resin as a binder, an epoxy resin and an additional intumescent additive - low molecular weight as a plasticizer and acceptor. compounds and oxidized graphite in the following ratio of components, wt. %:
Chlorinated PVC derivative - 6.5-14.9
Organosilicon resin - 6.5-14.9
Pentaphthalic Resin - 1.95-4.3
Polymer Phosphate Compound - At least 13
Epoxy - 1.3-2.1
Low Molecular Phosphate Compound - At least 13
Oxidized Graphite - At least 1.95
Pigment - 1.3-2.1
Solvent - Other

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