RU2680083C1 - Washing composition for cleaning metal surfaces - Google Patents

Abstract

FIELD: technological processes.SUBSTANCE: invention relates to the cleaning of metal surfaces from organic impurities in the inter-operational washing of aggregates, components in mechanical engineering, instrument making, transportation, and other industries. Washing composition for cleaning metal surfaces from organic impurities is described, comprising trisodium phosphate, disodium ethylenediaminetetraacetate, monoalkyl- or dialkylpolyglycol ether, dilithium pentaboric complex of Trilon B, glyceroborate of the general formula (CHO)BOH and water.EFFECT: enhancement of detergent and anticorrosive properties of detergent composition for cleaning metal surfaces.1 cl, 3 tbl

Description

The invention relates to detergent compositions for cleaning metal surfaces from organic contaminants, in particular petroleum products, lubricants, oils, and can be used for interoperative washing of aggregates and components in mechanical engineering, instrument making, transportation, and other industries.

Known detergents for cleaning metal surfaces from organic contaminants, containing surface-active substances (surfactants), defoamer, demulsifier, corrosion inhibitor, active ingredients (RU 2054034, C11D 1/72, 10.02.1996; SU 1004463, C11D 3/06, 03/15/1983). The disadvantages of the known detergents are low detergent and anti-corrosion properties when cleaning the metal surface.

Closest to the claimed technical solution is a detergent composition for cleaning metal surfaces containing trisodium phosphate, disodium ethylenediaminetetraacetate, monoalkyl- or dialkylpolyglycol ether, dilithium pentaborate complex of trilon B and water (RU 2629023, C11D 3/37, C11D 3/30, C11D 3/4, C11D 3/11, C11D 3/4, C11D 3/11, C11D 1/04, 08.28.2017).

The disadvantages of the known detergent composition are its low detergency to organic pollution when cleaning the metal surface and the lack of anti-corrosion properties.

The objective of the invention is to provide a detergent composition for cleaning metal surfaces from organic pollutants with improved detergent and anti-corrosion properties.

Technical result: increased detergent and anti-corrosion properties of the detergent composition for cleaning metal surfaces.

The technical result is achieved in that a detergent composition for cleaning a metal surface containing trisodium phosphate, disodium ethylenediamine tetraacetate, monoalkyl or dialkyl polyglycol ether, dilithium pentaborate complex of trilon B, according to the invention, additionally contains glyceraborate of the general formula (CH ₂ O) ₃ HVAC in the following ratio of components, %:

Trisodium Phosphate 1.5-2.5 Disodium ethylenediaminetetraacetate 1.0-1.5 Monoalkyl or dialkyl polyglycol ether 0.2-0.4 Diltiypentaboratny complex of Trilon B 0.5-1.0 Glyceroborate 0.5-1.0 Water rest.

The difference between the proposed solution from the known is the use in the detergent composition of glyceroborate of the general formula (CH ₂ O) ₃ VON, due to which an increase in the detergent and anti-corrosion properties of the solution is achieved.

The detergent composition is prepared by sequential dissolution in water with stirring of trisodium phosphate (GOST 201-76), disodium ethylenediaminetetraacetate (Trilon B, GOST 10652-73), monoalkyl or dialkyl polyglycol ether (GOST 8433-81), dilipium pentaborate Trilon B complex and glycerol glycerol ether and Glycol ether glycolic ester (GOST 8433-81), Trilone B, Trilon B and Glycol B, and glycol polystyrene ether (GOST 8433-81) The dilithium pentaborate complex of Trilon B was synthesized as described in the prototype. To do this, 1 liter of distilled water was placed in the reaction vessel and 378.0 g (2 mol) of lithium pentaborate and 336.0 g (1 mol) of trilon B were dissolved in it. The mixture was continuously stirred for 3-4 hours at room temperature. Then the solution was transferred to a crystallizer for growing crystals. The product yield was 686.9 g (or 96.2%) in terms of anhydrous salt. Chemical analysis found, wt. %: 50,32 - lithium pentaborate, and 44,86 - Trilon B. The refractive index of the obtained compound, measured by the immersion method, is equal to 1,372, and its density, found in benzene and toluene, is 1,482 g / cm ³ .

The formation of glyceroborate was established by research (Schwartz, EM. Interaction of boric acid with alcohols and hydroxy acids / EM Schwartz // - Riga: Zinatne. - 1990. - 414 p.). The glyceroborate of the general formula (CH ₂ O) ₃ VON is synthesized in the following way: 1 liter of distilled water is placed in the reaction tank and 92.0 g (1 mol) of glycerol and 62.0 g (1 mol) of boric acid are dissolved in it. The mixture is continuously stirred for 1-1.5 hours at room temperature. Then the solution is transferred to a crystallizer for growing crystals. Glyceroborate is a hygroscopic, glassy substance that softens at 150 ° C. The product yield is 114.9 g (97.4%). Chemical analysis found, wt. %: C - 30.46; B - 9.32. For the synthesized compound, the density was determined, which is equal to - 1.370 g / cm ³ ; as well as a molecular volume of 86.13 cm ³ / mol and a specific volume of 0.73 cm ³ / g.

The washing ability was determined by the method based on the determination of the percentage of washability of contaminants from the metal surface. For testing used parts with a surface roughness of 0.32-0.61 μm with a size of 100 × 50 × 1.5 mm. They were degreased with ether and kept for 5-10 minutes until complete evaporation of the ether and their adoption of a constant temperature. The parts were weighed on an analytical balance with an accuracy of 0.0001 g. Then organic glass was applied with a uniform layer with a glass rod. The amount of contamination applied should be approximately the same on all parts and be 0.080-0.085 g. Then the contaminated parts were placed in a laboratory washer and washed for 2 minutes. After washing, the parts were washed with distilled water and dried by blowing air from a fan at room temperature. After drying, they were weighed. The percentage of contamination removed from the surface was determined by the formula:

where P ₀ is the initial weight of the sample (pure), g;

P ₁ - the weight of the contaminated sample, g;

P ₂ - the weight of the sample after washing,

When determining the wetting ability, the samples (metal plates 150 × 70 mm in size) were first immersed in the prepared detergent solution and then distilled water for 10 seconds. Next, the samples were removed from the water and recorded the discontinuity of the water film visually. In this case, the surface remote from the edges and sharp edges less than 10 mm was not taken into account. Wetting ability is characterized by time, in seconds, from the beginning of the test to the rupture of a water film.

The compositions of the detergent compositions are given in table. one.

The results of the study of detergency and wettability are presented in table. 2

From table 2 it follows that when the content of the components in the detergent composition below the claimed boundary values (composition No. 1), the degree of purification (detergency) is 78.2%, which is worse than the claimed compositions 1.3 times and 1.9 times worse wettability In terms of detergency and wettability, detergent compositions of compositions No. 2, No. 3, No. 4, No. 5 are approximately the same. They allow you to almost completely clean the surface of samples from contamination. The known washing composition (prototype) cleans the surface only by 72.7%. Composition No. 5 has a fairly high quantitative content of the components, which is associated with a high consumption of material without a significant improvement in the detergent properties of the composition. Optimal detergent compositions are compositions No. 2, 3 and 4. Thus, in comparison with the known detergent composition (prototype), the proposed composition has higher quality indicators of the surface to be cleaned, which is associated with the introduction of glyceroborate.

Anti-corrosive properties of detergent compositions were studied by gravimetric method. For the tests used plates of steel Art. 10 size 120 × 10 × 1 mm from one batch, so its chemical composition, structure and mechanical properties were the same. Before testing, the surface of the samples was sequentially polished with emery paper of various grit, polished on a cloth until the scratches left from grinding were completely removed. Corrosion products from the surface of the samples were removed in inhibited acid (18% HCl + 0.5% metal corrosion inhibitor KI-1 (TU 6-04689381.006-97).

Tests of fully immersed ground and degreased samples were carried out in glass vessels with a ratio of solution volume to metal surface of 18-20 ml / cm ² . The exposure time of the samples in a corrosive environment (3% NaCl solution) was 10 days.

The effectiveness of the action of inhibitors was evaluated by the mass loss of the samples in the studied media. The corrosion rate (K) was calculated by the loss of mass of the samples, referred to the unit of surface per unit of time using the formula:

where m ₀ and m is the mass of the plate before and after the experiment, respectively, g; S - plate area, m ² ; t is the time of the experiment, h.

The inhibitory effect (inhibition coefficient), which shows how many times the inhibitor slows down the corrosion rate was calculated by the formula:

where K and K ₀ - corrosion rate in the presence and without inhibitor, respectively.

The degree of protection that characterizes the complete suppression of corrosion was determined in%:

The results of comparative studies of the anticorrosive properties of technical detergents are given in Table. 3

Anticorrosion studies show that the inventive detergent composition exhibits higher anticorrosive properties than the prototype.

The inventive detergent composition for cleaning metal surfaces from organic impurities, in particular petroleum products, lubricants, oils, and can be used for interoperational washing of aggregates and components in mechanical engineering, instrument making, transportation, and other industries.