RU2144944C1 - Cutting fluid concentrate - Google Patents

Abstract

FIELD: cold-working. SUBSTANCE: composition contains, wt %: boric acid di- or triethanolamine esters, 20- 25; di- or triethanolamine esters of oleic or synthetic C₇-C₁₀-fatty acids, 12- 15; corrosion inhibitor (interaction product of diethanolamine or triethanolamine with mono- and dialkyl phosphates containing mixture of fatty C₈-C₁₀-alcohols with tri-, tetra-, and more ethylene glycols at weight ratio 1:5 to 1:6), 5-25, and vegetable oil and animal fat soap stock, the balance. EFFECT: increased low-temperature (-15 C) stability, reduced corrosion activity, and 2-fold increased wear resistance of cutting teeth with no abrasive tool oiling.

Description

 The invention relates to compositions of cutting lubricants (COTS), in particular to concentrates of cutting fluids (coolant), which can be used in mechanical engineering for cold processing of materials by cutting and deformation and in other areas where there is a need for COTS and technical conservation detergents.

 Known emulsol of cutting fluid for machining metals, containing components in the following ratio, wt.%: Mineral oil 10-30, monoethanolamine 6-20, boric acid or a mixture of boric acid and non-inogenous surfactant in their mass ratio (2 5-14): 1 - 7.8-28 and water - the rest / RF Patent N 2041252, C 10 M 173/00 1995 /. A known tool containing a relatively large amount of water has a limited shelf life during storage, especially at sub-zero temperatures, which is negatively manifested during the subsequent use of working solutions in the metalworking process.

 Known concentrate cutting fluid for machining metals, containing components in the following ratio, wt.%: Mineral oil 20-35; the reaction product of triethanolamine with an unsaturated fatty acid boric acid 3-6; triethanolamine 10-18; bis (alkylpolyoxyethylene) phosphate 9-16 and water - the rest / RF Patent N 1383779, C 10 M 173/00 1995 /. The use of coolant increases tool life and reduces surface roughness. However, the presence of a large amount of triethanolamine in the concentrate affects the ecological properties of the coolant. Triethanolamine causes irritation to the skin of the hands, as well as corrosion of non-ferrous metals.

Closest to the claimed concentrate cutting fluid is a concentrate of protective lubricant, as described in the patent / Patent RF N 2050408, C 10 M 173/02, C 10 N 30:12, 1995 / containing components in the following ratio, wt. %:
Triethanolamine - 0.5 - 5.0
Dioxane Alcohols - 1.0 - 5.0
Dioxane alcohols boric esters - 20.0 - 30.0
Soap stocks of vegetable oils and animal fats - 10.0 - 20.0
The product of the interaction of triethanolamine (TEA) with monoalkyl-C ₁₀ -C ₂₀ phosphoric and / or dialkyl-C ₈ -C ₁₀ phosphoric acids and with maleic acid monoester or the product of the interaction of TEA with dialkyl dithiophosphoric acid or its zinc salt or with dibenzyl- or alkenylanthylate , or the product of the interaction of TEA with hydroxyethylidene diphosphonic acid and zinc sulfate - 2.0 - 20.0
Target additive: bactericide, dye, perfume - Not more than 4.5
Water - Up to 100
The known composition with sufficiently high performance characteristics has limitations when used, since the composition containing the products of the interaction of TEA with dialkyldithiophosphoric acid or its zinc salt or the product of the interaction of TEA with hydroxyethylidene diphosphonic acid or zinc sulfate is not stable in the presence of water, and decomposes with the release of acidic products , which affects the deterioration of inhibitory properties. The presence of free triethanolamine will lead to irritation of the skin of the hands and corrosion of non-ferrous metals.

 The objective of the invention is the creation of a concentrate of cutting fluid with high performance, environmentally friendly, stable when stored at low temperatures, allowing the use of working coolant solutions to increase tool life and the quality of the processed surface.

The task is achieved in that the concentrate cutting fluid contains components in the following ratio, wt.%:
Dimethylethanolamine or triethanolamine esters of boric acid - 20.0 - 25.0
Dimethylethanolamine or triethanolamine esters of oleic or naphthenic acids or synthetic fatty acids of the fraction C ₇ -C ₁₀ - 12.0 - 15.0
Corrosion inhibitor: The product of the interaction of dimethylethanol- or triethanolamine with mono- and dialkylphosphoric acids, in which a mixture of C ₈ -C ₁₀ fatty alcohols with tri-, tetra- or more ethylene glycols was used as an alcohol agent, in a mass ratio (1: 5-6 ) - 20.0 - 25.0
Target additive: perfume and antifoam - Not more than 0.1
Soap stock of vegetable and animal fats - Up to 100
Boric esters are prepared by reacting stoichiometric amounts of boric acid and dimethylethanol or triethanolamines during the preparation of the concentrate.

 Esters of oleic acid or naphthenic or synthetic fatty acids are obtained during the preparation of the concentrate by reacting stoichiometric amounts of these acids with dimethylethanol or triethanolamine. The resulting esters have emulsifying, dispersing, penetrating and inhibitory properties.

 Soap stocks of vegetable oils and fats are a by-product of the production of margarine formed during the refining of vegetable oils: sunflower, soy, rapeseed, cottonseed and animal fats and the corresponding salomas - hydrogenated oils and fats / TU 10-0402-80-91 /. Soap stocks include glycerides (up to 15%), soaps of unsaturated and saturated acids (up to 25%) and glycerin (impurities), the rest is water. Natural fats - glycerides and soaps - have lubricating, extreme pressure properties due to the creation of boundary lubrication.

 Incoming soaps increase the polarity of the coolant, at the same time the ability to hold them on the surface of the metal being treated increases, thereby protecting the coolant.

 As a perfume, any known aromatic essential water-soluble oils are used.

 Effective aqueous solutions of organosilicon compounds, for example, grade KE-10-34, are used as antifoam.

A corrosion inhibitor is the product of the interaction of dimethylethanol or triethanolamine with mono-, dialkylphosphoric acids, in which a mixture of C ₈ -C ₁₀ fatty alcohols with tri-, tetra- and more ethylene glycols was used as an alcohol agent, in a mass ratio of 1: (5- 6).

The process of obtaining a corrosion inhibitor is as follows. First, a mixture of C ₈ -C ₁₀ fatty alcohols with tri-, tetra- and more ethylene glycols is added to phosphoric acid with a molar ratio of phosphoric acid: alcohols equal to 1: (0.5-1), then dimethylethanol- or triethanolamine is added to the resulting product in a mass ratio of 1.5-1, while the product of the interaction of these components is a mixture of dimethylethanol- or triethanolamine esters of phosphoric acid / up to 20% / with a mixture of dimethylethanol- or trimethylethanolamine esters of mono-, dialkylphosphoric acids / up to 80% /.

 The resulting product of the interaction of dimethylethanol- or triethanolamine with phosphoric acid esters is a water-soluble product that is prepared and stored separately, corrosion-resistant with respect to metals and introduced into the coolant concentrate in the required quantities. In addition, it can be used in some cases on its own.

 Preparation of cutting fluid concentrate is as follows.

The calculated amount of dimethylethanol- or triethanolamine is loaded into the apparatus with a mechanical stirrer and heating, the required amount of oleic or naphthenic, or synthetic fatty acids of the C ₇ -C ₁₀ fraction is added; with constant stirring, the mixture is heated to 90-95 ^o C, maintained at this temperature for 1.5-2 hours, then the required amount of boric acid is charged and kept at a temperature of 85-90 ^o C for no more than 2 hours, while pH of the medium is not lower than 8.5.

Then, the previously obtained phosphorus-containing corrosion and soap stock inhibitor is sequentially loaded into the resulting mixture of components and stirred at a temperature of 70-75 ^° C for 1-1.2 hours. Then, at 45-50 ^° C, the target additives are introduced: perfume and antifoam, and again mixed for 15 minutes until a homogeneous product of a transparent consistency is obtained.

 The table shows the compositions of the coolant concentrate in accordance with the formula and the properties of its 3% solution.

Thus obtained concentrate cutting fluid is a dark brown oily liquid, readily soluble in water with the formation of translucent solutions with a pH of 8.5-9.3, having a density of 1040-1080 kg / m ³ at 20 ^o C.

The concentrate is stable for a long time when stored at low temperatures (-15 ^o C). The properties of the 3% solution of the compositions of the examples show that the tendency to foam is 250-300 cm, the stability of the foam 29-33 cm, which is a positive factor in the processing of metals. Corrosion activity in accordance with GOST 6243 with respect to cast iron shavings on steel withstands for 168 hours.

 A 3% solution of coolant composition was tested when processing a part of a CT-6 cylinder. It is shown that during grinding there is no salting of the abrasive tool, there are no burnt parts. During the test, there were no signs of corrosion, odor, biodefeat, exposure to the machine paint, increased foaming, flux deposits on the surface of the part and the bed. In addition, the use of the inventive coolant can improve the durability of the abrasive tool.

 Positive results were also obtained when turning a heat-resistant nickel-based alloy EK 78 (ХН 65 КВ МУТБ) with cutters equipped with multifaceted VK 8 hard alloy plates.

 Tests of coolant samples (according to the prototype) and the proposed composition were carried out at a cutting speed of V = 35 m / min, a feed of S = 0.18 mm / rev and a cutting depth of t = 0.5 mm. For the blunting criterion, wear at the rear edge of the cutter equal to 0.45 mm was taken.

 Analysis of the test results showed that the resistance of the cutters was 25 minutes when working with the proposed coolant, the roughness of the worked surface corresponded to the requirements of GOST, and 12 minutes when working with coolant according to the prototype.

 A number of other tests in production and laboratory conditions showed that the inventive coolant can be used at a concentration of 2.5-5.0% in water as a detergent and preservative in machine-building enterprises, as well as in caring for auto and agricultural machinery.

 The technology for its production is non-waste. There are no air emissions.

Claims (1)

A cutting fluid concentrate containing boric acid esters, a corrosion inhibitor, and target additives — soap stocks of vegetable oils and animal fats, characterized in that it additionally contains dimethylethanolamine or triethanolamine esters of oleic or naphthenic acids, or naphthenic acids, or synthetic fatty acids of fraction C ₇ - C ₁₀ , as boric acid esters, the concentrate contains dimethylethanolamine or triethanolamine esters of boric acid, as a corrosion inhibitor it is a reaction product dimethylethanolamine or triethanolamine with mono- and dialkylphosphoric acids containing, as an alcohol agent, a mixture of C ₈ - C ₁₀ fatty alcohols with tri-, tetra- or more ethylene glycols, in a mass ratio of 1: 5 - 6 in the following ratio, wt.%:
Dimethylethanolamine or triethanolamine esters of boric acid - 20.0 - 25.0
Dimethylethanolamine or triethanolamine esters of oleic or naphthenic acids, or synthetic fatty acids of fraction C ₇ - C ₁₀ - 12.0 - 15.0
Specified corrosion inhibitor - 20.0 - 25.0
Target additives: perfume and antifoam - Not more than 0.1
Soap stock of vegetable and animal fats - Up to 100

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