RU2090584C1 - Undercoat for anticorrosion coating - Google Patents

Abstract

FIELD: production of water resistant and anticorrosion undercoats for urethane, acryl urethane and epoxy coatings for protection of articles of aircraft technique against corrosion. SUBSTANCE: undercoat for anticorrosion coatings possessing improved adhesion features and anticorrosion protection of aluminium and magnesium alloys and steels is proposed. Undercoat comprises binder on the base of epoxy diane resin, titanium dioxide, talc used as filler, strontium chromate used as anticorrosion pigment, hardener and organic solvents wherein undercoat additionally comprises modifying agent on the base of acrylic acid, barium chromate and zinc molybdate (used as anticorrosion pigments), silica powder as filler and organosilicon amine as hardener. Undercoat comprises, mas.p.: epoxy diane resin, 100; modifying agent on the base of acrylic resin, 10-20; strontium chromate, 10-20; barium chromate, 20-40; zinc molybdate, 20-40; titanium dioxide, 20-40; talc, microtalc, 25-40; silica powder, 5-12; hardener on the base of organosilicium amines, 30-50; organic solvents, 400-600. EFFECT: improved properties.

Description

 The invention relates to the field of waterproof anticorrosive primers applied under urethane, acrylurethane, acrylic and epoxy enamels for corrosion protection of parts, assemblies and assembled aircraft products from various alloys (aluminum, magnesium alloys, steel).

Known primer AK-070 (GOST 25 18-83) yellow, including a polymer binder based on acrylic resin with the addition of another polymer resin, anticorrosive pigment-strontium chromic acid and organic solvents. Primer AK-070 is intended for priming aluminum, magnesium alloys and steels in coating systems with acrylic and epoxy enamels. Primer cold drying, quick drying at a temperature of 18-23 ^o C 1 hour. However, the technological and protective properties of the primer AK-070 are insufficient: the coating has a low gas and oil resistance, does not withstand the action of the hydraulic fluid NGZh-4, which is used on modern aircraft, has low protective properties. In addition, the primer AK-070 is characterized by increased toxicity due to the high content of highly toxic anti-corrosive pigment-strontium chromate (MPC = 0.01 mg / m ³ ).

 The closest in technical essence to the claimed composition of the primer is a primer EP-076 (TU 6-10-755-84), consisting of epoxy and polyamide resins, pigments and filler in a mixture of organic solvents.

 The primer EP-076 is supplied complete in the form of two components: paste EP-076T and hardener N 2.

 Primer EP-076 is intended for painting parts from magnesium alloys and steels.

The composition of the primer: parts by weight (assuming 100% substance):
Epoxy Dianova Resin 100
Anticorrosive pigment strontium chromate 60
Titanium Dioxide Pigment 45
Talc Filler 45
Hardener-polyamide resin 50
Organic Solvents 370
EP-076T paste is a suspension consisting of epoxy resin, pigments and a filler in a mixture of organic solvents; hardener N 2 30% solution of polyamide resin in a mixture of organic solvents.

Primer EP-076 is used mainly with coating drying at 90-100 ^o C for 1-2 hours and in coating systems with epoxy-polyamide enamels. EP-076 primer has low adhesion to the aluminum alloy, the main material for covering aviation products, and the primer is destroyed by the action of the coating NGZ-4 and is quite toxic, because contains a large amount of anticorrosive pigment-strontium chromate.

 The primer EP-076 is taken as a prototype for the claimed composition of the primer.

 An object of the invention is the creation of a primer for corrosion protection of aluminum, magnesium alloys and steels with improved adhesive and protective properties, moisture resistant, resistant to hydraulic fluid НЖЖ-4, technological, stable during long-term storage and less toxic. The primer is intended for coating systems for acrylurethane, urethane, acrylic and epoxy enamels.

A primer of the following composition, wt.h. (assuming 100% substance):
Epoxy Diane resin E-41p (TU 6-10-607-78) 100
Modifier-acrylic resin BMK-5 (TU 6-02-115-91) 10-20
Anti-corrosion pigments:
strontium chromate (TU 48-4-239-82) 10-20
barium chromate (TU 6-09-5286-86) 20-40
zinc molybdate (TU 301-10-034-90) 20-40
titanium dioxide (GOST 9808-84) 20-40
Fillers:
talc or microtalc (TU 21-25-201-77, GOST 19284-79) 25-40
Aerosil (GOST 14922-77) 5-12
Hardener product based on organosilicon amines AGM-9 (TU 6-02-724-77) 30-50
Organic solvents: xylene (GOST 9949-76, GOST 9410-78) acetone (GOST 2768-84) butyl acetate (GOST 89-81) ethyl cellosolve (GOST 8313-88) - 400-600
The inventive primer differs from the primer of the prototype in the composition of the binder-film-forming; pigments and fillers; hardener:
the introduction of an acrylic modifier and the use of hardener AGM-9, instead of a polyamide hardener, is caused by the requirement to use a primer as a cold-drying coating due to the need to apply a primer to assembled and large-sized products and, at the same time, subjected to wetting with НЖЖ-4 hydraulic fluid;
the use of barium chromate (MPC = 0.1 mg / m ³ ) and zinc molybdate (MPC = 1.0 mg / m ³ ) as anticorrosive pigments and a decrease in strontium chromate to reduce the toxicity of the primer;
introduction of Aerosil to improve the stability of the primer during storage.

An example implementation of a primer primer consists of:
semi-finished product, which is a suspension of pigments and fillers in a solution of epoxy-dianovoy resin,
modifier, which is a solution of acrylic resin BMK-5 (a copolymer of butyl methacrylate and methacrylic acid),
hardener AGM-9,
which are mixed before application.

 Prefabricated primers are made by dispersing pigments and fillers in a solution of epoxy-diane resin in a ball or bead mill. Upon reaching the required degree of milling, the contents from the mill are pumped to the mixer, solvents are added, and the semi-finished product is set according to viscosity and non-volatile content.

 The modifier is made in the reactor by dissolving BMK-5 acrylic resin in a solvent mixture of xylene, acetone and butyl acetate.

Before applying the primer to the semi-finished product, a modifier and hardener are added, the primer is diluted with organic solvents and applied to a metal surface, mainly using a spray gun. The drying time of the primer is 3-6 hours at a temperature of 12-35 ^o C. Then overlap with 2-3 layers of acrylic enamel or 2 layers of urethane, acrylurethane, epoxy enamel.

 Table 1 shows the compositions of the claimed primer, primer with exorbitant amounts of components, primer prototype.

 Table 2 presents the properties of primers and coating systems, in comparison with the primer-prototype EP-076, applied to various alloys (aluminum and magnesium) and steel.

 As follows from the data obtained, the proposed primer is superior to the primer prototype.

 The inventive primer, as such, and in coating systems with acrylic, acrylurethane, urethane and epoxy enamels provides adhesion to the aluminum alloy, while the prototype primer in the corresponding coating systems loses adhesion when the coating is wetted.

Gives the adhesive properties to the primer:
acrylic modifier,
hardener-organosilicon amine AGM-9,
a reduced content of strontium chromate due to the introduction of more water-resistant anti-corrosion pigments — barium chromate and zinc molybdate, resulting in a decrease in the osmotic influx of moisture into the coating.

 The inventive primer is resistant to the action of hydraulic fluid НЖЖ-4 (primer prototype is destroyed). The stability of the claimed primer to NGZ-4 is provided by the hardener AGM-9 and anti-corrosive pigments barium chromate and zinc molybdate.

 When testing in a wet chamber coating systems with the inventive primer and with acrylic, acrylurethane, urethane and epoxy enamels, the alloys deposited on the aluminum alloy remain unchanged and have adhesion for a long time, while bubbles with a prototype primer form and breaks adhesion.

 When accelerated testing in a salt spray chamber of a coating system with the claimed primer, applied to an aluminum alloy, and followed by an incision of the coating, retain the protective properties remain unchanged (there is no violation of the coating from the incision) and there are no corrosion damage.

 The protective anticorrosive effect of the claimed primer coating, despite the reduced, compared with the prototype, the content of strontium chromate is provided by the regulated ratio of strontium chromate with low toxic anti-corrosion pigments barium chromate and zinc molybdate.

 Coating systems with the inventive primer and acrylurethane, urethane and epoxy enamels applied to low alloy steel and to an oxidized magnesium alloy also provide corrosion protection during salt spray testing in a chamber.

 Due to the fact that the epoxy prefabricated primer is a multiphase system, during long-term storage, pigment sedimentation and sedimentation occur, especially due to barium chromate and zinc molybdate. The addition of Aerosil to the primer prevents pigment settling during storage of the semi-finished product.

 To improve the technological properties of the primer, when applied to the primer, titanium dioxide is introduced, as a result of which the hiding power of the primer is increased.

 From the data obtained it also follows that the inventive primer provides requirements for the protection of an aluminum alloy of the main alloy for external sheathing of products due to the combined action of the components when they are contained in certain declared quantitative ratios, which is confirmed by the results on the properties of coatings, in comparison with the compositions of primers with an beyond components.

 The introduction of an acrylic modifier into the primer below the lower limit leads to a decrease in the adhesive properties of the coatings when wet (Example 5). The reduced transcendental content of the hardener also negatively affects the adhesion of the primer (example 6). In addition, a significant decrease in the adhesion of the primer coating occurs with an increased prohibitive content of strontium chromate and titanium dioxide in the primer (example 5) and a prohibitively low content of barium chromate and zinc molybdate (examples 7 and 9), which also leads to a decrease in the protective properties of coatings during testing in a wet chamber.

 The resistance of the coatings to the liquid NGZh-4 decreases with a prohibitively low amount of AGM-9, a prohibitively high content of acrylic modifier (example 6) and a prohibitively low content of barium chromate and zinc molybdate (examples 7 and 9).

 The protective anticorrosive effect of coatings during accelerated salt spray test (with a preliminary notch of the coating) decreases with an extremely low content of strontium chromic acid and hardener AGM-9 in the primer (Example 6), as well as with a low modifier content and with an extremely high titanium dioxide content (example 5).

 With a prohibitively increased content of barium chromate and zinc molybdate and a prohibitively reduced content of aerosil (examples 8 and 10), a dense, difficult to mix sediment forms during storage of the epoxy prefabricated primer.

 With a prohibitively high content of Aerosil (Example 9), the viscosity of the semi-finished primer during storage increases.

 When the content of titanium dioxide is extremely low (Example 6), the opacity of the primer coating during application is reduced.

From the obtained results of tests of primers, it follows that on the basis of an epoxy binder with an acrylic modifier and hardener based on organosilicon amine, with a pigment part containing a relatively small amount of strontium chromate (MPC = 0.01 mg / m ³ ), low-toxic anti-corrosion pigments: barium chromic acid (MPC = 0.1 mg / m ³ ), zinc molybdate (MPC = 1.0 mg / m ³ ), titanium dioxide, fillers: talc (or microtalc), aerosil and with organic solvents (xylene, acetone, butyl acetate, ethyl cellosolve) The primer composition intended for anticorrosive protection of metal surfaces of products (aluminum, magnesium alloys, steels) of aviation equipment for coating systems for acrylic, acrylic, urethane and epoxy enamels is given.

 Primer cold drying, technological, stable during storage of components (semi-finished product, modifier and hardener).

 Coating systems using the proposed primer composition have increased performance (operational resistance) due to good adhesion, resistance to the action of hydraulic fluids, and protective anticorrosive action.

 The primer is designed to protect aluminum, magnesium alloys and steels.

 The proposed primer helps to increase the life of the coating system by 1.5 times.

Claims (1)

 Primer for anticorrosion coating, including a polymeric binder based on epoxy-dianov resin, titanium dioxide, talc filler, anticorrosive pigment strontium chromic acid, hardener, organic solvents, characterized in that it additionally contains an acrylic resin modifier, anticorrosive pigments barium chromate and molybdenum zinc and Aerosil filler and as a hardener - an organosilicon amine in the following ratio of components, wt. Epoxy Dianova Resin 100
Acrylic resin modifier 10 20
Strontium chromate 10 20
Barium chromate 20 40
Zinc Molybdate 20 40
Titanium dioxide 20 40
Talc, microtalc 25 40
Aerosil 5 12
Hardener organosilicon amine 30 50
Organic solvents 400 600v

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