RU2201435C2 - Emulsion oil for preparing water-mixable lubricating fluid - Google Patents

Abstract

FIELD: lubricants. SUBSTANCE: emulsion oil contains, wt %: base oil with kinematic viscosity 5-40 sq.mm/s (50 C), 30-50; mixture of polyoxyethylene glycol ethers of synthetic primary fatty alcohols fraction C16-C20, 25-45; polymethylsiloxane, 0.06- 0.12; sodium tripolyphosphate, 4-10; bactericide-anticorrosion additive, in particular product of reaction of esterified mixture of di- and trimethylolurea with phosphoric acid salt, 4-10; and ethylene glycol, the balance. EFFECT: enhanced anticorrosion and bactericide properties and preserved functional properties at low temperatures (from -10 to -30 C). 2 tbl, 5 ex

Description

 The invention relates to the field of application of cutting lubricants in metal processing processes. It can be used in the machine-building industry, namely, water-miscible cutting fluids (coolant) used in the machining of metals.

 It is known that for the preparation of coolant emulsols of various types (liquids, pastes) are widely used, containing an oil base, emulsifier (various types of surfactants), stabilizer (alcohols, glycols), various specific additives and additives (antifoam, anticorrosive, bactericidal) .

For example, in (Dubrovsky, Yu.S., Rumyantseva, T.A., Chugay, G.N., Operational properties of water-miscible cutting lubricants. - K.: UkrNIIITI, 1991, Issue 2, p. 4 and Berdichevsky E.G. Lubricating and cooling agents for processing materials. Handbook. M .: Mashinostroenie, 1984, p. 81) it is indicated that emulsols containing mineral oils, an emulsifier based on tall oil, stabilizers (alcohols and glycols) are widely used for the preparation of coolant and additives (for example, bactericidal - hexachlorophene). The disadvantages of these emulsols include:
- corrosion of coolant based on them,
- loss of functional properties of emulsol during storage at low temperatures due to the presence of water in it.

 - monofunctionality, toxicity and poor water solubility of hexachlorophene additive.

For a number of metalworking operations, coolant based on emulsol is used, which is described in (Kurchik N.N., Vainshtok V.V., Shekhter Yu.N. Lubricants for metal cutting. - M .: Chemistry, 1972, p. 137) and consisting of mineral oil, emulsifier (sodium sulfonate) and various additives (anti-corrosion - sodium nitrite, trisodium phosphate, soda ash). The disadvantages of this emulsol include:
- monofunctionality of additives.

- toxicity of sodium nitrite,
- low biostability
- instability during storage (precipitate).

The closest (prototype) to our proposed emulsol is emulsol, described in (Berdichevsky EG Lubricating and cooling agents for processing materials. - Reference book. M: Engineering, 1984, p. 82), which is a mixture of mineral oil; emulsifier - petroleum sodium sulfonates, extract of transformer distillate, triethanolamine; anticorrosive additives (sodium nitrite). The main disadvantages of the prototype include:
- toxicity of sodium nitrite and triethanolamine,
- loss of functional properties of emulsol during storage at low temperatures due to the presence of water in it.

- the use as the main lubricating component of mineral oil with kinematic viscosity at 50 ^o C in a narrow range of 9.5-12.5 mm ² / s, which does not allow the use of coolant based on this emulsol in a wide range of metalworking operations,
- high price.

 The objective of the invention is the production of emulsol for the preparation of water-miscible coolant with improved performance properties.

The technical essence of the invention lies in
the preparation of emulsol containing the following components, wt.%:
Basic oil base with kinematic viscosity at 50 ^o C 5-40 mm ² / s - 30-50
Emulsifier - 25-45
PMS-200A antifoam additive or equivalent - 0.06-0.12
Sodium Tripolyphosphate - 4-10
Bactericidal anti-corrosion additive - 4-10
Ethylene Glycol - Else
As an emulsifier use syntanol ACTSE-12 brand, which is a mixture of polyoxyethylene glycol ethers of synthetic primary higher fatty alcohols of the C ₁₆ -C ₂₀ fraction.

 The bactericidal anti-corrosion additive is a neutralized product of the interaction of an esterified mixture of di- and trimethylolurea with a salt of phosphoric acid.

 PMS-200A antifoam additive or an analogue is an organosilicon liquid or, otherwise, polymethylsiloxane.

 A common feature for the prototype and invention is the presence in their formulation of mineral oil.

Distinctive features of the prototype and invention are as follows:
- in the prototype, sodium sulfonates of oil, extract of transformer distillate, triethanolamine are used as emulsifiers, in the invention the emulsifier is syntanol AC-SE-12;
- in the prototype, sodium nitrite is used as an anti-corrosion additive and there is no bactericidal additive, the bactericidal anti-corrosion additive is used in the invention and sodium tripolyphosphate is additionally added to enhance the anti-corrosion properties;
- the invention uses ethylene glycol, which is a stabilizer, in the prototype ethylene glycol is absent;
- the invention uses the anti-foam additive PMS-200A (or equivalent), the latter is absent in the prototype.

 Obtaining samples of emulsols and bactericidal anti-corrosion additives, as well as testing the functional properties of the proposed emulsol are shown in the following examples.

 Example 1. The synthesis of bactericidal anti-corrosion additives.

 To obtain a mixture of di- and trimethylol urea, 10 ml of a 70 wt.% Urea solution and 40 ml of 37 wt.% Formalin were loaded into a reaction flask with a stirrer and reflux, heated to boiling, kept for 40 minutes.

To esterify the mixture, 100 ml of n-butanol was added and held for 7 hours. After exposure, the esterified mixture was cooled to 40-45 ^° C and 60 ml of a 50 wt.% Solution of disodium phosphate salt heated to 20-30 ^° C were added. After 4 hours, the mixture was cooled, alcohol was separated on a separatory funnel, and 100 ml of a 15 wt.% Caustic soda solution was added to the water-soluble (lower) layer. The precipitated flocculent precipitate was filtered under vacuum and dried at room temperature to constant weight. As a result, we got 40 grams of the product. The structure of the substance is not clearly established.

 Example 2. Obtaining emulsol.

Emulsols were prepared as follows:
- at the first stage, in a container with a mixer, the base oil base was mixed with the synthesized ACSE-12 brand syntanol heated to a liquid state at a temperature of 40-60 ^o C for 20-60 minutes,
- then at the same temperature ethylene glycol and an antifoam additive were successively introduced and mixed for 20-60 minutes,
- in the third stage, the mixture was cooled to a temperature of 25-30 ^o C, a bactericidal anticorrosion additive and sodium tripolyphosphate were added sequentially and mixed until a homogeneous pasty state for 20-60 minutes.

 The composition of two samples of emulsols obtained according to example 2, are presented in table 1.

 The experiments showed that the use of ATSSE-12 syntanol as an emulsifier makes it possible to obtain water-miscible coolant using oils of various grades (in a wide range of viscosity indicators) and origin.

The obtained samples of emulsols do not have water in their composition, and therefore, unlike most of the used emulsols, they retain their functional properties in the low temperature range (-10 ÷ -30 ^o C). This has been confirmed by research.

 Example 3. Determination of the bactericidal properties of the coolant.

 Determination of the bactericidal properties of the coolant prepared from the emulsol according to example 2 was carried out according to the method described in (Lubricating-cooling technological means for metal cutting: Handbook / Under the general editorship of S. G. Entelis, E.M. Berliner. - 2- ed., revised and enlarged., M.: Mechanical Engineering, 1995, p. 361).

 The coolants prepared using the emulsol composition of example 2 (see table. 1, sample 1, 2) and the same emulsol were tested, but without a bactericidal anti-corrosion additive.

 The preparation of the coolant was carried out by mixing emulsols with water in a ratio (by volume) of 1: 9, respectively (using sample 1) or 1: 19 (using sample 2). These ratios are due to the required performance properties of the coolant.

Then the coolant samples were infected with bacteria and kept for several days at a temperature of 30 ± 5 ^o C. After that, the degree of biodefeat of the coolant samples was determined.

 As a result of the tests, it was found that the coolant prepared from emulsol without a bactericidal anti-corrosion additive had a limit IV biodefeat score (completely contaminated with coolant, not suitable for further use) on a V-point scale (from 0 to IV), and coolant prepared from emulsol with a bactericidal anti-corrosion additive had a 0-I point, which corresponds to the good performance properties of the coolant.

 Example 4. Determination of the anticorrosive properties of the coolant.

 The anticorrosive properties of the coolant prepared from emulsol according to example 2 were evaluated according to the method described in (Lubricating-cooling technological means for metal cutting / Handbook / Under the general editorship of S.G. Entelis, E.M. Berliner. - 2nd ed., rev. and add., Moscow: Mashinostroenie, 1995, p. 357, 358).

 The coolants prepared using the emulsols of the composition according to example 2 (see table. 1, sample 1, 2) and the same emulsols, but not containing bactericidal anti-corrosion additives and sodium tripolyphosphate, were tested.

 The preparation of the coolant was carried out by mixing emulsols with water in a ratio (by volume) of 1: 9, respectively (using sample 1) or 1:19 (using sample 2).

 As a result of the tests, it was found that the coolant prepared from emulsol without a bactericidal anti-corrosion additive and sodium tripolyphosphate had a corrosion score of IV (V-scale from 0 to IV points), which corresponds to a strong degree of corrosion. Coolant prepared on the basis of emulsol with a bactericidal anticorrosive additive and sodium tripolyphosphate (see Table 1) had a score of 0, which corresponds to the absence of corrosion.

 Example 5. Industrial tests of coolant.

 The conditions and results of industrial tests of the coolant prepared from the emulsol according to example 2 are presented in table. 2.

 It is shown that the coolant based on the proposed emulsols have high performance properties. In addition, the emulsols themselves do not have toxic additives, and also retain their functional properties after storage at low temperatures. In emulsols, a multifunctional bactericidal anticorrosive additive is used, which makes it possible to give the coolant high anticorrosion properties and biostability. By changing the base oil base of emulsol, coolant can be used on a much wider range of metalworking operations. The method of obtaining emulsol is simple and does not require significant energy consumption.

Claims (1)

Emulsol for the preparation of a water-miscible cutting fluid containing the following components, wt. %:
Base oil base with kinematic viscosity at 50 ^o C 5-40 mm ² / s - 30-50
A mixture of polyoxyethylene glycol esters of synthetic primary fatty alcohols fraction C ₁₆ -C ₂₀ - 25-45
Polymethylsiloxane - 0.06-0.12
Sodium Tripolyphosphate - 4-10
Bactericidal-anticorrosive additive, which is a neutralized product of the interaction of an esterified mixture of di- and trimethylolurea with a salt of phosphoric acid - 4-10
Ethylene Glycol - Else

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