RU2156268C1 - Composition for protective coating - Google Patents

Abstract

FIELD: aqueous wax protective compositions from atmospheric effects, ageing, biodamages of industrial rubber, polymeric, metallic, wooden products and paint coatings. SUBSTANCE: composition comprises water, and petroleum ceresin with drip point of 65-98 C. Emulsifier includes mono- and disubstituted amides of synthetic fatty C₁₇-C₂₁ acids of monoethanolamine triborate. EFFECT: higher effectiveness of the protective coating and reduced cost price of the composition. 2 cl, 1 dwg, 4 tbl

Description

 The invention relates to the field of protection, in particular to protective compositions against weathering, aging, biodeterioration of rubber-technical and polymer products, unpainted surfaces of wood, metal, painted decorative coatings of woodworking and machinery in transportation conditions, and can be used in all industries for conservation equipment for storage in open areas.

The practice of using water-wax compositions for applying protective coatings has shown that the composition of the composition must satisfy a number of technological requirements that provide:
uniformity of coating on the surface to be protected by any method (spraying, dipping, brush);
the formation on the protected surface of a continuous plastic-hard, back non-emulsifiable and indelible coating;
coating resistance at temperatures from minus 50 ^o C to plus 60 ^o C;
fire safety and non-toxicity;
surface protection under storage conditions in an open area for a period of not less than three years;
resistance of the coating to microorganisms.

 The compositions ZVVD-13 (TU 38.101716-78 "Protective water-wax composition ZVVD-13") and IVVS-706M (TU 38.401123-86 "Inhibited water-wax composition IVVS-706M") are widely used, the formulation of which contains ceresin dispersion an aqueous solution of ammonia, a composition based on a car preservative (TU 6-15-870-78 "Car preservative") containing a waxy substance, emulsifier, ammonia and water.

The disadvantages of the above compositions are:
low resistance (less than 6 months) of the protective coating obtained on their basis to the effects of aggressive environments: salt fog, sea water, sulfur dioxide, due to violation of the uniformity of the coating as a result of cracking and peeling at negative (below minus 20 ^o C), runoff (washing off by atmospheric precipitation) at elevated (above plus 25 ^o C) temperatures due to a decrease in the adhesive and plasticizing properties of the coating from a waxy substance in a composition with an emulsifier;
insufficient resistance to microorganisms and biodeterioration due to lack of biocidal properties;
toxicity of compounds based on organic solvents and aqueous ammonia solutions (when applying a protective coating by pneumatic and airless spraying, the compositions form highly hazardous aerosols, which, according to the degree of exposure to the human body, belong to hazard class 2 (GOST 121.007-76 "hazard classes of harmful substances") and require conservation work in insulating respiratory protection);
insufficient inertness to coatings, rubber goods and polymeric materials (at the time of coating formation - application of the composition, organic solvents and aqueous ammonia solutions interact with the coating material, reducing its adhesion and decorative properties, and when interacting with rubber goods and polymeric materials worsen fuel and frost-resistant properties of these materials).

 The above disadvantages of the known protective coatings based on water-wax compositions lead to significant restrictions on their use for their intended purpose and reduce the economic efficiency of the application.

 The closest in technical essence to the proposed invention is a composition for a protective coating on a water-wax basis (GDR patent N 22805, CL 22 G 7/02, 1959 - prototype), including a waxy substance (montanwax, ceresin, paraffin fraction), emulsifier (synthetic fatty acids, straight-run gasoline, ammonia) and water.

 The disadvantage of this composition is the low resistance of the coating, toxicity and a high degree of fire hazard, because it is combustible due to the presence of straight-run gasoline, which requires strict observance of safety rules when applying and storing the protective composition, and complex component composition (the presence of montan wax, ceresin, paraffin fraction, synthetic fatty acids, straight-run gasoline, ammonia) leads to an increase the cost of coverage with insufficient effective protection.

 The technical result is an increase in the effectiveness of the protective coating while reducing the cost of the composition.

The specified technical result is achieved by the fact that the known composition for a protective coating containing a waxy substance - ceresin, emulsifier and water, according to the invention as a waxy substance contains oil ceresin with a dropping point of 65-95 ^o C, and as an emulsifier - monosubstituted amides fractions synthetic fatty acids C ₁₇ -C ₂₁ triborate monoethanolamine in the following ratio, wt.%:
Petroleum ceresin with a dropping point of 65-95 ^o C - 15.0 - 25.0
Monosubstituted amides of the FFA fraction C ₁₇ -C ₂₁ triborate monoethanolamine - 2.0 - 8.0
Water - Else
and also the fact that it additionally contains disubstituted amides of the synthetic fatty acid fraction of C ₁₇ -C ₂₁ monoethanolamine triborate in an amount of 0.5-1.5 wt.%.

Comparative analysis with the prototype (table. 1) led to the conclusion that the claimed composition for the protective coating differs from the known introduction of new components, namely mono- and disubstituted amides of the FFA fraction C ₁₇ -C ₂₁ triborate of monoethanolamine, oil ceresin with a dropping point of 65- 95 ^o C.

 Thus, the claimed technical solution meets the criterion of "novelty."

 Analysis of the known formulations for the protective coating showed that the substances introduced into the inventive composition are known.

It is known to use mono- and disubstituted amides of the FFA fraction C ₁₇ -C _{21 of} monoethanolamine triborate ^* as corrosion inhibitors (Bregman J. Corrosion inhibitors. -L .: Chemistry, 1978, 264 pp.), Boric acid and its derivatives as biocides ( Gerasimenko A.A. Protection against corrosion, aging, and biodeterioration of machines, equipment, and structures.-M.: Mechanical Engineering, 1987, 686 p.).

- однозамещенные амиды фракции СЖК C₁₇-C₂₁ трибората моноэтаноламина. ^*

- monosubstituted amides of the FFA fraction C ₁₇ -C _{21 of the} triborate of monoethanolamine.

- двузамещенные амиды фракции СЖК C₁₇-C₂₁ трибората моноэтаноламина.

- disubstituted amides of the FFA fraction C ₁₇ -C _{21 of the} triborate of monoethanolamine.

Mono- and disubstituted amides of the FFA fraction C ₁₇ -C _{21 of the} triborate of monoethanolamine are nitrogen-containing compounds that are used in industry as widespread surfactant corrosion inhibitors.

Oil ceresin with a dropping point of 65-95 ^o C is a high molecular weight paraffin hydrocarbon from isostructure, is widely used in the production of greases as a thickener, has good adhesive properties.

 Given the above properties of known ingredients, the authors conducted research on the possibility of using them together in a composition for protective coating of products.

 To substantiate the quantitative composition, prototypes with different concentrations of components were prepared (Table 2). Coatings based on specimen compositions underwent accelerated laboratory and field tests (GOST 9.054-75, "Preservation oils, lubricants and inhibited film-forming compounds. Accelerated protective ability tests"; GOST 9.050-75 "Paint coatings. Laboratory tests for resistance to mold mushrooms. "). The test results are given in table. 3, show that all formulations are superior to ZVVD-13, IVVS-706M in mushroom resistance (30 days of testing), protective properties in aggressive environments, and under full-scale tests.

The inventive composition confirms the achievement of a technical result (dropping point of the dry residue of 83.4 - 86.7 ^o C; protective properties with respect to St. 3,% corr. Surface damage: in sea water after 250 hours, in a salt fog chamber after 100 hours , in the weather-compensating chamber IP-1.3 after 500 hours; during field tests after 36 months - 0; mushroom resistance after 30 days - withstands; conditional viscosity on VZ-4 13.0 - 28.0 s; stability during centrifugation 15 , 0 - 25.0 min; wholesale price 385 - 625 rubles / t) and meets the technological requirements m (Article 3, Table 3).

 Thus, the technical result is achieved using samples 2 - 4 and 7 - 9, which confirms the quantitative composition of the claimed limits of the ingredients.

 To confirm the effectiveness of the claimed composition in relation to the well-known and widespread, an experimental batch of the claimed composition was prepared (samples 3, 7). The test results are presented in table. 4. These trains passed full-scale tests during the preservation of tankers ATsZ - 4.1 - 131 in an open area.

 The drawing shows a block diagram of a technological installation for preparing a composition for a protective coating.

The composition is prepared as follows. Mono-substituted and disubstituted amides of the FFA C ₁₇ -C ₂₁ monoethanolamine triborate fraction are loaded into the heated mixer 1 in a predetermined quantity, water and the mixture are brought to a temperature of 90-95 ^o C with stirring, after which a ceresin melt with a dropping point of 65- is introduced into the mixer 95 ^o C. Maintaining the temperature of the mixture of all components at a level of 90-95 ^o C, produce mixing gear pump 2 to obtain a homogeneous and immiscible emulsion. To stabilize the properties of the emulsion during storage, it is subjected to homogenization by pumping in a closed circle by a plunger pump 3 through a homogenizing device 4 (throttle valve) under a pressure of 10-15 MPa, then collected in a collection of finished products 5. The composition is ready for use.

The use of oil ceresin with a dropping point of 65-95 ^o C in combination with mono- and disubstituted amides of the FFA fraction C ₁₇ -C _{21 of} monoethanolamine triborate (as shown by tests) allowed us to create a composition for a protective coating that is not inferior in properties to the inhibited aqueous wax composition IVVS-706M with a significant reduction in cost and the presence of biocidal properties (table. 3).

 The claimed technical solution meets not only the criterion of "novelty" (difference from the prototype), but also differs by inventive step, since the authors do not have information about the claimed combination of using known components.

 The composition is easy to prepare and consists of commercially available components, which allows you to prepare a composition for a protective coating on the job.

 The annual economic effect of using the proposed composition instead of the commercially available composition of the ZVVD-13 minus the additional capital costs of research, development and organization of production in the amount of 3000 tons / year will be 800 rubles / ton.

Claims (1)

1. The composition for a protective coating containing a waxy substance - ceresin, emulsifier and water, characterized in that as a waxy substance contains oil ceresin with a dropping point of 65 - 95 ^o C, and as an emulsifier - monosubstituted amides of the fraction of synthetic fatty acids C ₁₇ -C ₂₁ triborate monoethanolamine in the following ratio, wt.%:
Petroleum ceresin with a dropping point of 65 - 95 ^o C - 15.0 - 25.0
Monosubstituted amides of the FFA fraction C ₁₇ -C ₂₁ triborate monoethanol - 2.0 - 8.0
Water - Else
2. The composition for a protective coating according to claim 1, characterized in that it further comprises disubstituted amides of the synthetic fatty acid fraction of FFA C ₁₇ -C ₂₁ monoethanolamine triborate in an amount of 0.5-1.5 wt.%.

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