RU2777442C1 - Means for washing vehicle parts - Google Patents

Abstract

FIELD: detergents.

SUBSTANCE: invention relates to detergents used for washing metal surfaces of vehicle parts being restored during repair from contamination with grease films, deposits, corrosion products and oil-resinous impurities, and can be used as a new effective detergent in repair production at enterprises of agro-industrial and motor transport complexes. A detergent for cleaning vehicle parts from contamination is described, based on synthanol DS-10 or DT-7; oxyphos or estephate; sodium trisodium phosphate or disodium phosphate, sodium tripolyphosphate; sodium metasilicate, sodium carbonate, sodium sulfate, in which ammonium tetraborate is additionally used to increase the washing ability, wettability and anticorrosive properties.

EFFECT: increase in the detergent and anticorrosive properties of the detergent composition.

1 cl, 3 tbl

Description

The invention relates to detergents used for washing metal surfaces of vehicle parts, restored during the repair process, from contamination with fatty films, carbon deposits, corrosion products and oily-resinous contaminants and can be used as a new effective detergent in repair production at agro-industrial enterprises and transport complexes.

The high adhesion of contaminants of different composition and properties, the complex configuration of the surfaces of the parts necessitate the use of detergents that increase the quality of washing and labor productivity, provide protection of the surfaces of the cleaned parts from corrosion during the interoperation period of storage.

There are three basic requirements for detergents:

- high degree of purification, defined as the ratio of the mass of removed contaminants to the mass of contaminants before washing (%);

- high wetting ability, determined by the length of time (in seconds) from the moment the sample is removed from the washing solution until the water film breaks on its surface. The longer this time, the higher the wetting and washing power of the detergent;

- maximum protection of the cleaned parts from corrosion during the interoperation period of storage, determined by the length of time (in days) from the moment the washing is completed until the first corrosion centers appear on the washed surface without additional conservation coatings.

Known detergent composition for cleaning metal surfaces, containing, wt. %: 2.5-8.0 neonol; 5.0-10.0 trisodium phosphate; 5.0-30.0 sodium metasilicate; 10.0-40.0 sodium hydroxide; 1.0-2.5 sodium chloride; 5.0-10.0 sodium sulfate; 0.5-1.0 carbamide and the rest is water (analogue) [1]. However, this composition is intended for use in the dairy industry, and is not suitable for removing fatty films, soot, corrosion products and oil-resinous contaminants from the surfaces of vehicle parts.

The closest in technical essence to the proposed tool is a synthetic detergent Temp-100 (prototype), containing, wt. %: 1.5 sintanol DS-10 or DT-7 (surfactant); 0.5 oxyphos or estefate, 20 trisodium phosphate (or 25 disodium phosphate), 15 sodium tripolyphosphate, 10 sodium metasilicate, 26 sodium carbonate, sodium sulfate up to 100.

Temp-100 is a free-flowing powder from white to light yellow, highly soluble in water, used at a concentration of 5-10 g/l in an aqueous solution. Washing is carried out at a temperature of 85-90 ° C in mechanized washing installations with a bath with a capacity of up to 1.0-1.2 m ³ for washing liquid, a rotating table located under it for laying parts to be washed, jet nozzles for supplying washing liquid, a heater washing liquid. The duration of direct washing is 5-10 minutes.

The disadvantage of this tool is: low wetting ability of such contaminants as soot and oily-resinous deposits, relatively low washing power (no more than 75-80%) and low anti-corrosion properties (lack of effective corrosion inhibitors in the composition).

The purpose of the proposed invention is to improve the detergent and anti-corrosion properties of the detergent composition.

This goal is achieved in that the cleaning solution for cleaning and degreasing a metal surface containing sintanol DS-10 or DT-7; oxyphos or estefate; trisodium phosphate or disodium phosphate; sodium tripolyphosphate; sodium metasilicate, sodium carbonate additionally contains ammonium tetraborate in the following ratio, wt. %:

sintanol DS-10 or DT-7 1.5 oxyphos or estefate 0.5 trisodium phosphate 20 (or disodium phosphate - 25) sodium tripolyphosphate 15.0 sodium metasilicate 10.0 sodium carbonate 26.0 ammonium tetraborate 0.5-1.0 sodium sulfate up to 100

In the patent and scientific and technical literature, technical solutions similar to the proposed one are not known, which allows us to conclude that the proposed composition meets the conditions of patentability - "novelty".

Such a ratio of components in the presence of ammonium tetraborate makes it possible to obtain an obvious positive effect, i.e. the proposed composition satisfies the conditions of patentability - "inventive step".

The composition is used for industrial washing of contaminated surfaces of parts during the maintenance and repair of vehicles. It is made from compounds produced by the domestic industry, therefore, it meets the conditions of patentability - "industrial applicability".

The composition was tested in accordance with the requirements for detergent compositions.

1. Detergency tests were carried out on test specimens with dimensions of 2×30×100 (mm) cut from St3sp steel sheet. The edges were deburred, and a hole 5 mm in diameter was drilled at a distance of 1 mm from the edge to form bags and hang them in the test solution. Removed the products of preliminary corrosion, scale, degreased with Viennese lime, washed with distilled water (at room temperature), dried between sheets of filter paper. Weighed on an analytical balance VLA-200 g-M with an accuracy of 0.0005 g, data on weight (M ₀ ) were recorded in the test log. As an artificial contamination, a mixture of used engine oil and resinous deposits from the centrifuge of the diesel engine lubrication system was used in a ratio of 2:1. The contamination was applied to one side of the test sample with a spatula, leveled over the surface with a manual brush. The samples were weighed, the results (M ₁ ) were recorded in the test log, and the mass of contaminants was determined (M ₁ -M ₀ ).

The package of samples was formed leaving a gap of 15 mm between the samples. The bags were placed in a laboratory washing machine with the tested washing solution at a temperature of 85-90°C.

Laboratory washing installation [2] consists of a double-wall thermostatic bath with a capacity of 5 liters of washing solution, which is excited by an electric motor-reducer with a propeller stirrer rotating at a frequency of 90-120 min ^-1 . The solution was heated through a jacket located around the bath by pumping water at the required temperature from a TS-24 thermostat. The temperature of the liquid was controlled by a thermometer mounted in the liquid bath.

After washing for a specified time, the package with test samples was removed from the washing solution, kept at room temperature for 4-4.5 hours until the samples were completely dry. The bags were dismantled and weighed each sample with the remaining contamination (M ₂ ). The data was logged.

The degree of purification was determined by the formula:

2. Wetting a contaminated surface with a solution of a detergent is the primary act of the washing process, because detergent comes into contact with the surface to be cleaned. The better this contact, the stronger the washing effect, ceteris paribus. Conversely, when there is no wetting, there is no washing effect.

The measure of wetting is usually the contact angle between the tangent to the surface of the liquid, drawn from the point of contact of three surfaces (solid, liquid, and gaseous), and the projection of this tangent onto the surface of the solid.

The wettability index of detergents in our studies was determined in the following way.

Metal samples 70 × 150 (mm) in size, after preliminary cleaning from corrosion products and scale, were first immersed in the prepared detergent solution, and then in demineralized water for 10 s. Next, the samples were taken out of the water and the discontinuity of the water film was visually recorded using a magnifying loupe. In this case, the surface removed from the edges and sharp edges by less than 10 mm was not taken into account. Wetting ability is characterized by the length of time from the beginning of the test to the break of the water film.

3. The anticorrosive properties of the cleaning solution were determined by the length of time (in days) from the moment the washing was completed in the solutions of the tested compositions until the first corrosion centers appeared on the cleaned surface without applying protective compositions.

This method is substantiated by the fact that the interoperation period of storage of parts of repaired units and assemblies usually does not exceed 15-30 days. Detergents, after drying, form a protective film on the surface of the cleaned part. If the detergent has an anti-corrosion property (there is a corrosion inhibitor in the composition), then the electrode potential of the metal is shifted in the positive direction.

The studies were carried out in two washing environments: in the solution of the prototype (Temp-100) and in the solution of the proposed composition. The conditions of the experiment were identical: the temperature of the washing solution 85-90°C, the duration of washing 8 min, the concentration and prototype, and the proposed composition of 65.0-75.0 g/l.

In table. 1 shows the results of a study of the degree of purification of contaminated parts in laboratory conditions in solutions of the prototype and the proposed composition.

From Table. 1 shows that the degree of purification of the solution of the proposed composition is much higher than that of the solution of the prototype. This confirms the property "usefulness" of the proposed invention.

In table. 2 shows the results of a study of the wettability of solutions of the prototype and the proposed composition.

Table data analysis. 2 shows that the wettability of the solution of the proposed agent is significantly higher than that of the solution of the prototype.

In table. 3 shows the results of a study of the anti-corrosion properties of solutions of the prototype and the proposed tool.

From Table. 3 shows that the anti-corrosion properties of the solution of the proposed tool is higher than that of the prototype solution by 94.3%.

Literature

1. Detergent composition [Text]: Pat. 2179998 Ros. Federations: IPC C11D 1/72, C11D 3/04, C11D 3/075 / Khadaev T.I.; applicant and patent holder Khadaev Timur Ilyich; dec. 03/27/00; publ. 27.02.02.

2. Telnov, N.F. Technology of cleaning and washing of agricultural machines [Text]: monograph / N.F. Telnov. - M.: Kolos, 1073. - 295 p.

Claims (2)

Detergent for cleaning and degreasing a metal surface containing sintanol DS-10 or DT-7; oxyphos or estefat; trisodium phosphate or disodium phosphate, sodium tripolyphosphate; sodium metasilicate, sodium carbonate, sodium sulfate, characterized in that to increase the detergency, wettability and anti-corrosion properties, it additionally contains ammonium tetraborate, in the following ratio, wt. %: sintanol DS-10 or DT-7 1.5 oxyphos or estefate 0.5 trisodium phosphate 20 (or disodium phosphate - 25) sodium tripolyphosphate 15.0 sodium metasilicate 10.0 sodium carbonate 26.0 ammonium tetraborate 0.5-1.0 sodium sulfate up to 100