RU2169165C1 - Anticorrosion paintwork compound - Google Patents

Abstract

FIELD: preparation of mono-and multiplier coatings, such as primers, enamels for protection of steel structures, products and equipment operating under conditions of intensive atmospheric effects against corrosion in industrial and civil engineering, in engineering structures and water-development projects operating under higher humidity conditions and industrial and power plants, equipment for chemical and petrochemical industries, port facilities ship building, and motor industry. SUBSTANCE: claimed paintwork compound comprises polyurethane lacquer, highly dispersed zinc powder prepared by evaporating metallic zinc in neutral gas atmosphere followed by condensation thereof, rheological additive and organic solvent, ratios of components being as follows, wt %: polyurethane lacquer 13.6- 24.4; said highly dispersed zinc powder, 71.1-79.5; rheological additive, 0.3-0.5; and organic solvent, the balance. Rheological additive includes microtalc for paint and varnish industry and/or benton SD or modified castor oil. Invention makes is possible to prepare single-packing paintwork compound with prolonged storage period without irreversible changes in properties. Said compound has high anticorrosion and chemical resistance of surface being treated in aggressive media at elevated temperatures. EFFECT: higher mechanical and adhesion properties of the paintwork compound. 5 cl, 2 tbl _

Description

 The present invention relates to a single-packaging paints and varnishes containing metal powders, and is intended for the manufacture of single and multilayer coatings such as primers, enamels for corrosion protection of steel structures, products and equipment operating in conditions of intense atmospheric exposure, including vapors of mineral and organic acids and alkalis, marine and fresh water environments, and can be used in industrial and civil engineering, engineering and hydraulic structures operating in high humidity, industrial and power plants, chemical and petrochemical industry equipment, port facilities, shipbuilding and automotive industry.

 Anticorrosion compositions are known in science and technology that contain polymeric binders, modifying additives, corrosion inhibitors, and active fillers that are resistant to weathering.

 For example, a composition is known for anticorrosive protection of a steel surface, containing an organo-diluting film former, which is used as a modified polyethylene glycol maleate phthalate resin, and the product of the interaction of allyl alcohol and toluene diisocyanate with a polyisocyanate (Aut. Certificate. SU N 1473326. IPC C 09 D 508 175/06, 1994).

 The known composition provides only mechanical protection of the surface from weathering. During operation, the coating cracks to form cracks, and when surface defects occur on the coating during corrosion of the steel surface, sublayer and ulcerative corrosion occur.

 To improve the mechanical stability of the anticorrosion coating, the Ureplen urethane-bitumen composition is known, including, by weight: binder - a polybutadiene urethane prepolymer, which is the product of the interaction of toluene diisocyanate with polytetrafurandiol and / or polybutylene glycol adipate, 100, liquid bitumen 100-80, powdery (cement, gibs, chalk, kaolin) 2.5-5. (Application RU N 94035362/03, IPC C 09 D 175/04, 195/00, C 08 L 95/00, 1996).

 The known composition has increased ductility and mechanical properties, however, in the presence of surface defects of the coating, the corrosion protection of the steel surface is insufficient.

 To improve corrosion resistance is known composition containing, by weight. h: binder - polystyrene waste 15-16, coal tar 3.5-4.9, corrosion inhibitor - quinoline derivative 0.016-0.02, zinc powder 15-16, alumina 7-8, the rest as a solvent. (Aut. Certificate. SU N 1737909, IPC C 09 D 5/08, C 09 D 125/06, 1998).

 The introduction of zinc powder and a corrosion inhibitor somewhat increases the anticorrosion properties, however, it is impossible to carry out electrochemical (tread) surface protection using a known composition, i.e. the coating obtained from the known composition does not provide corrosion protection for metal surfaces, and is also characterized by low adhesive properties.

 Closest to the proposed one is a one-pack highly filled anticorrosive paint composition comprising, parts by weight: binder - a mixture of polyvinyl butyral and polymethylphenylsiloxane 10-15, a filler - a mixture of powdered zinc, aluminum and kaolin 110-120, the target additive is an acid corrosion inhibitor, which is used as alcohol solution of polyacrylic and methacrylic acid, 0.5-3.0 and an organic solvent - a mixture of aliphatic alcohols 85-90. (Patent RU N 2058357. IPC C 09 D 129/14, 183/04, 5/08, 1996).

 The known coating has a fairly good corrosion resistance and elasticity, which ensures long-term operation of products in environments with increased aggressiveness, but when applied to the surface it is difficult to achieve a uniform layer thickness, and due to the heterogeneity and friability of the coating in individual, “weakest” areas foci of ulcerative corrosion occur. In addition, the known composition during the formation of the coating does not provide high adhesion to the metal, which is a prerequisite for preventing sublayer corrosion, and does not provide tread (cathodic) protection for steel, as a result of which corrosion of the main occurs in defective places of the coating - pores, scratches, chips metal.

 The tread protection of highly zinc-coated coatings consists in the fact that zinc and steel form a galvanic pair, where zinc is the anode, and in defective places zinc is oxidized, and not the metal on which the coating is applied. With a high filling of the coating with zinc, its particles come into contact with each other. This provides electrical conductivity of the coating and cathodic protection of steel. It is known that effective tread protection of steel by the cathodic mechanism when using zinc-containing coatings is provided when the zinc content in the dry coating film is more than 80%.

 The objective of the invention is the creation of a single-pack paint composition with a long shelf life without irreversible changes in properties, providing high corrosion and chemical resistance of the treated surface in aggressive environments at elevated temperatures with increased mechanical and adhesive properties.

The problem is solved in that the proposed composition contains a binder, zinc powder, the target additive and an organic solvent, while polyurethane varnish is used as a binder, highly dispersed powder obtained by the gas-phase method by evaporation of zinc metal in a neutral gas atmosphere is used, followed by its condensation, as a target additive, a rheological additive is used in the following ratio of components, wt.%:
Polyurethane varnish - 13.6-24.4
The specified fine powder of zinc - 71.1-79.5
Rheological additive - 0.3-0.5
Organic Solvent - Else
As a polyurethane varnish, one-pack polyurethane varnishes are used, obtained by reacting an oligoester with isocyanates, for example, Laptex-2 brand (TU 2226 001 13013487-95), manufactured on the basis of Laprol 5003 polyester or Laprol 4503 with an excess of diphenylmethane diisocyanate (MDI) environment with the formation of a polymer film.

 As a highly dispersed zinc powder, an industrially produced powder of the PCVD brand (highly dispersed zinc powder) is used, obtained by evaporation of metallic zinc in an atmosphere of a neutral gas (atmosphere of inert gases or nitrogen) followed by its condensation.

 As a rheological additive, microtalc is used for the paint and varnish industry, and / or benton or SD benton, or a modified hydrogenated castor oil of the MPA - 1078x, MPA 2000x grades, manufactured by Rheox (Germany). Bentons are commercially available under the brands Benton 27, Benton 38, Benton SD-3, Benton 34, Benton SD-1, Benton SD-2 and are layered silicate - smectite (hectorite or bentonite), the surface of which is modified by a long-chain organic compound.

Ketones, acetates, hydrocarbons, for example white spirit (Nefras C ₄ 150/200) according to GOST 3134-78 butyl acetate according to GOST 22300-76 and their mixtures in effective proportions are used as an organic solvent.

 Comparison of the proposed composition with the known allows us to conclude that the claimed invention meets the criterion of "novelty", because the proposed composition contains a new combination of ingredients in a new quantitative ratio.

Fine zinc powder and urethane varnishes are widely used in various paint compositions. Their combined use in the claimed composition allows to achieve a new technical result - an unobvious improvement in anticorrosion, adhesive and mechanical properties, an increase in the shelf life of the composition and the provision of protective protection of the treated surface under the influence of aggressive environments at elevated temperatures. Providing tread protection is achieved due to the high content of powdered zinc in the composition, which ensures its content in the coating of more than 80%. In known zinc-filled compositions, the introduction of an increased amount of zinc powder leads to a deterioration in the stability of the composition, coating and aesthetic indicators due to the formation of zinc agglomerates and a deterioration in the rheological parameters of the paint. In the claimed composition, the use of finely dispersed zinc powder obtained by evaporation and condensation in an atmosphere of a neutral gas followed by condensation gives new properties that are mainly due to phase transformations of zinc (solid zinc-vapor-liquid-solid zinc powder), which allows to obtain annealed structure of zinc in the form of dendrites with increased ductility. As identified by the applicant, the use of this zinc powder allows you to get a new technical result and solve the problem - to provide tread protection without compromising the adhesive properties inherent in the binder. The mechanism of the formation of the structure of the anticorrosive composition is ensured by the properties of the binder and the properties of highly dispersed zinc powder. When finely dispersed zinc powder is introduced into the polyurethane binder, a stable colloidal structure is formed, which is micelles interacting with each other, formed by zinc particles enclosed in a binder shell. The rheological additive is introduced to provide the desired viscosity, while the spherical shape of the zinc particles and the flexible plate shape of the particles of the rheological additive provide the ability to create a dense uniform flowing structure of the claimed composition. The resulting micelles containing zinc particles as a nucleus interact with each other and upon curing form a continuous zinc-containing layer that provides protective tread protection that is resistant to water, solvents of acids and alkalis. The zinc content in the dry coating is provided from 80 to 90 wt. % The continuity and uniformity (uniformity) of the coating depends on the uniformity and strength of the binder shell on the zinc particles, which is determined by the claimed quantitative ratio of the ingredients of the composition. The resulting composition has an optimal consistency with a density of 2.1-3.3 g / m ³ , which is easily applied by all known methods. The resulting coating is characterized by high adhesion to the machined surface, optimal elasticity, resistance to cracking and cracking during operation, corrosion resistance and heat resistance. After drying of the claimed composition, the resulting surface has the appearance of a smooth film (from semi-gloss to matte) of light gray color without craters and sagging, wrinkles and foreign inclusions. All of the above allows us to conclude that a new technical result is obtained - obtaining a coating that provides tread protection of the treated surface under aggressive environmental conditions at elevated temperatures, which meets the criterion of "inventive step".

 The proposed composition can be made from materials known in the industry, using known equipment. This allows us to conclude that the claimed invention meets the criterion of "industrial applicability".

 The inventive composition is prepared as follows.

 An organic solvent (butyl acetate or its mixture with white spirit in a ratio of 1: 1) is mixed with a rheological additive (microtalc for the paint and varnish industry and / or Benton SD-3) in the dissolver in the claimed amount, the claimed amount of highly dispersed PCVD zinc powder is introduced with stirring Laptes-2 urethane varnish is added and mixed until tender. The compositions of the examples of specific performance are shown in table 1. The composition is unloaded from the dnssolver to the mixer for ripening, and then poured into a packaging container. Preparation of test samples is carried out in accordance with GOST 8832, surface preparation in accordance with GOST 8832 and GOST 9.402. As a material for all types of tests, except for bending strength, low-carbon steel type 08kp, 08 ps, St. 3 with a sheet thickness of 10 mm. Surface preparation of samples includes solvent cleaning (acetone, white spirit, solvent N 645, 646, 647, 648) and shot-blasting (sandblasting). The surface roughness according to Rz is 30-50 microns. Samples for bending strength are prepared according to current GOST. If necessary, the composition before application is adjusted to the required working viscosity with solvents 645, 646, 647 and 648 by adding no more than 5 wt.% Of its weight. Corrosion treatment of a standard steel sample is carried out by airless pneumatic spraying or with a brush or roller on a previously prepared surface. The resulting coating is dried under natural conditions 15 - 120 minutes When determining the drying time and physico-mechanical parameters, the coating thickness is not less than 60-80 microns, which corresponds to 1 layer of the composition. When evaluating the protective properties, the coating thickness is at least 70-80 microns (1 layer of the composition). Before testing the physical and mechanical properties, the samples are kept at room temperature for at least 48 hours, and the protective properties for 7 days. The drying time is determined according to GOST 19007, the adhesion of the coating to a metal surface is assessed according to GOST 15140, method 2, impact strength is determined according to GOST 4765. The elasticity of the coating during bending is determined according to GOST 6806. The paint density is determined according to GOST 28513. The viscosity is determined by the VZ viscometer. -246, nozzle 4 mm according to GOST 8420. The mass fraction of non-volatiles is determined according to GOST 17537. The resistance of the coating to the static effects of liquid media is evaluated according to GOST 9.403. method A. Samples are tested in 25% solutions of sulfuric acid according to GOST 367-73 and sodium hydroxide according to GOST 4328-77. After the test, visually determine the state of appearance. The state of the metal under the coating is determined visually, for which the coating is removed with a scalpel. Heat resistance is determined according to OST 6-10-422-78, resistance at elevated temperatures in the presence of sodium chloride - according to ISO 4623. The data obtained are shown in table 2.

 As can be seen from the above data, coatings based on the claimed compositions have high mechanical properties, high impact resistance and abrasion resistance, resistance to aggressive environments in which all other zinc-filled compounds are not stable: organic solvents, vapors of mineral and organic acids, hydrogen sulfide, sulfuric and sulfur dioxide . These properties make it possible to use the claimed compositions for processing equipment operating in highly aggressive conditions at elevated temperatures, where other known coatings are ineffective: storage tanks for sulphurous iron in sulphate plants, bins and racks with various mineral fertilizers, sulphurous ore sinter, protection of containers and pipes for storage and transportation of sulphurous oil and fuel oil, gas purification equipment and other equipment and structures.

 The manufacture of compositions in quantitative proportions that do not correspond to the claimed results in a decrease in acid resistance and chemical resistance, a decrease in ductility and shelf life, and loss of the tread protection mechanism.

The inventive compositions are used as an independent coating or in an integrated multilayer coating on pre-prepared surfaces of equipment, metal structures, as well as concrete and reinforced concrete structures operated in the open air and indoors at a temperature not exceeding 160 ^o C.

Claims (4)

1. An anticorrosive paint composition containing a binder, zinc powder, a target additive and an organic solvent, characterized in that a polyurethane varnish is used as a binder, and highly dispersed zinc powder obtained by gas-phase evaporation of zinc metal in a neutral gas atmosphere is used as zinc powder its subsequent condensation, as a target additive, a rheological additive is used in the following ratio of components, wt.%:
Polyurethane varnish - 13.6 - 24.4
The specified fine powder of zinc - 71.1 - 79.5
Rheological additive - 0.3 - 0.5
Organic Solvent - Else
2. Anticorrosive paint composition according to claim 1, characterized in that as a rheological additive use microtalc for the paint industry.  3. The anticorrosive paint composition according to claim 1, characterized in that benton or benton SD is used as a rheological additive.  4. The anticorrosive paint composition according to claim 1, characterized in that microtalc for the paint industry and benton or benton SD are used as a rheological additive.  5. The anticorrosive paint composition according to claim 1, characterized in that a modified hydrogenated castor oil is used as a rheological additive.

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