RU2102428C1 - Coolant liquid for internal combustion engine - Google Patents

Abstract

FIELD: coolant liquids. SUBSTANCE: invention proposes coolant liquid based on ethylene glycol an aqueous solution without nitrite, nitrate, benzoate, phosphate and molybdate. Liquid has additionally high-boiling fractions M-2. Coolant liquid has, wt.-%: ethylene glycol, 54.50-65.50; sodium tetraborate, 0.1-0.3; benzotriazole, 0.35-1.00; high-boiling fractions M-2, 0.5-0.7; and water, the balance. Coolant liquid is inert with respect to steel, cast iron, aluminium alloys and solder. Its corrosion activity with respect to copper and brass is 5.0-7.3-fold less as compared with the known liquids. Rubber swelling is decreased by 4.8-fold. Liquid does not show foaming. EFFECT: enhanced quality and property of coolant, improved ecology. 4 tbl

Description

 The invention relates to compositions of low-freezing liquids, namely, cooling liquids, used primarily as a coolant in cooling systems of internal combustion engines.

Known coolant for internal combustion engines based on an aqueous solution of ethylene glycol containing sodium tetraborate, sodium molybdate dihydrate, sodium benzoate, polyorganosiloxane. The specified antifreeze at elevated temperatures (80 90 ^o C) has a low anti-sedimentation properties and contains toxic products: sodium molybdate dihydrate and sodium benzoate [1]
The closest in technical essence is a coolant containing in wt. up to 90 95 alcohol, preferably ethylene glycol; 0.1 - 5.0 organic additive C ₆ -C ₁₂ aliphatic monobasic acid or its salt; 0.1 5.0 sodium tetraborate; 0.1 5.0 tolyltriazole or benzotriazole. To prepare the coolant, the concentrate is diluted by adding 25 75% wt. water [2]
The specified antifreeze has good anticorrosive properties with respect to all structural materials of cooling systems of internal combustion engines, however, the foaming capacity exceeds the permissible limits established by GOST.

 The aim of the invention is to reduce the corrosive activity of structural materials of cooling systems of internal combustion engines and reduce foaming.

 To achieve this goal, a coolant containing ethylene glycol, water, sodium tetraborate, benzotriazole and an organic additive contains, as an organic additive, high-boiling fractions M-2, a mixture of by-products of the stage of isolation of morpholine from the catalysis of the production of morpholine from diethylene glycol and ammonia in the following ratio of components, wt.

Ethylene glycol 54.50 65.50
Sodium tetraborate 0.10 0.30
Benzotriazole 0.35 1.00
High boiling fractions M-2 0.50 0.70
Water rest
In the above composition, "High-boiling fractions M-2" are by-products of the catalytic synthesis of morpholine from diethylene glycol and ammonia at 215 260 ^o C and 0.02 0.06 MPa on a nickel-chromium catalyst in the presence of hydrogen, isolated from the catalyst of this process at the stage of separation rectified morpholine.

In the catalytic synthesis of morpholine from diethylene glycol and ammonia at 215,260 ^° C and 0.02 0.06 MPa on a KSM-3A nickel-chromium catalyst [GOST 6-03-314-75] in the presence of hydrogen per 1 ton of the desired morpholine product, 0.316 tons of by-products are formed.

At the stage of separation of morpholine rectified from the cube, partial boilers for the catalysis of the above process are selected high-boiling by-products bottoms with a specific gravity of 1.06 1.12 g / cm ³ and a light fraction of by-products with a specific gravity of 0.76 - from the top of the column 1.00 g / cm ³ . The light fraction mainly consists of heterocyclic amines: tetrahydro-1,4-oxazine and its methyl and ethyl substituted, methylethylamine, water and up to 2% of unidentified products.

A mixture of the above bottoms and light fractions of the stage of isolation of morpholine from the catalysis of the catalytic synthesis of morpholine from diethylene glycol and ammonia at 215 260 ^o C and 0.02 0.06 MPa on a nickel-chromium catalyst in the presence of hydrogen is the "High-boiling fractions M-2 according to T 6-14-10-210-87 ", which have a composition, wt.

tetrahydro-1,4-ethyloxazine 0.8 7.2
tetrahydro-1,4-methyloxazine 1.7 3.0
tetrahydro-1,4-oxazine 0.8 8.4
2-amino-2 ¹ -oxydiethyl ether 1.2 2.0
2.2 ¹ -diaminodiethyl ether 0.4 0.8
2,2-dimorpholinoethyl ether 20.8 23.8
ethylene glycol 0.8 1.7
ethylene glycol methyl ester 0.4 1.3
methylethylamine 0.7 1.4
2-methoxyethylamine
0.8 1.7
2-hydroxy-2-morpholinodiethyl ether 0.7 1.4
unidentified products up to 1.6
water 4.0 9.2
diethylene glycol rest
"High-boiling fractions M-2 according to TU 6-14-10-210-87" are a dark brown liquid, highly soluble in aqueous solutions of ethylene glycol. It has a specific odor and density of 1.05 1.12 g / cm ³ , has an alkaline character, a 0.5% aqueous solution has a pH of 12.5 units.

In the proposed composition of the coolant:
the maximum concentration of ethylene glycol is selected in order to ensure the temperature of the onset of crystallization of the coolant is not higher than minus 45 ^o C;
the maximum concentration of the buffer additive (sodium tetraborate) is selected to ensure that the pH of the coolant is in the range of 7.5-8.5 units. since with the addition of 0.5 0.7% wt. The "high boiling fractions M-2" pH of the coolant without sodium tetraborate becomes higher than 12.0 units. and at such pH values, the coolant becomes corrosive to aluminum and its alloys. Sodium tetraborate in the composition of the proposed coolant is not only a buffer additive, but also an inhibitor of corrosion of copper, brass, carbon steel, cast iron, aluminum. At the same time, sodium tetraborate in the proposed coolant initiates solder corrosion. Therefore, in addition to the above, the upper limit concentration of sodium tetraborate is also limited by the fact that a further increase in its concentration in the coolant leads to a sharp increase in corrosion of the solder. The lower limit concentration of sodium tetraborate is limited by the increase in the corrosive activity of the coolant with respect to cast iron, aluminum, steel, brass, copper (the row is located in the decreasing degree of influence);
benzotriazole in the proposed coolant is an inhibitor of corrosion of solder, aluminum, steel, cast iron, copper (a number is located according to the degree of decreasing influence) and a stimulator of corrosion of brass. The upper limit concentration of benzotriazole is limited by an increase in brass corrosion above the allowable limit and an increase in aluminum corrosion when all three corrosion inhibitors (benzotriazole, sodium tetraborate and high boiling fractions M-2) are combined in the coolant, a negative interaction effect. The lower limit concentration of benzotriazole is limited by an increase in corrosion of solder, aluminum, steel and copper with a further decrease in the concentration of benzotriazole in the coolant;
in the proposed composition of the coolant "High-boiling fractions M-2" are corrosion inhibitors of cast iron, steel, aluminum, brass, copper (a series of decreasing protection effects) and inert to solder. With this in mind, the maximum concentration of “High-boiling fractions M-2” is limited by an increase in the corrosion of cast iron, steel, aluminum, brass and copper, and the upper one by an increase in the corrosion of aluminum has a negative interaction effect when the high-boiling fractions M-2 are combined with sodium tetraborate and benzotriazole in the coolant.

Almost all known cooling fluids foaming to varying degrees. The formation of foam in coolants of cooling systems of internal combustion engines can lead to disruption of such systems: the occurrence of cavitation and other undesirable phenomena. To prevent the indicated in cooling systems, known coolants almost always contain antifoam agents, and at the same time, the expandability of coolants and the disappearance of foam in them are limited to safe operating limits. So, according to GOST 28084-89, the foam volume during foaming of cooling low-freezing liquids is limited to "no more than 30 cm ³ ", and the foam stability is "no more than 3 s."

 In the proposed coolant "High-boiling fractions M-2" completely prevent the formation of foam, therefore, they are used in this liquid not only as an effective corrosion inhibitor of structural materials of cooling systems of internal combustion engines, but also as an effective antifoam.

The corrosion properties of the proposed coolant and the assessment of its other main indicators were carried out in full accordance with the research methods given in GOST 28084-89 on the coolant liquid was determined according to section 4.6. GOST 280084-89;
the crystallization onset temperature was determined according to clause 4.3. GOST 28084-89;
The corrosive properties of the coolant were investigated in accordance with paragraph 4.5. GOST 28084-89, while copper M-1 according to GOST 859 was used as the studied metals; brass L-63 according to GOST 2208; steel 20 in accordance with GOST 1050; cast iron Сч24-44 in accordance with GOST 1412; Al-9 aluminum according to GOST 2689; POS 40-2 solder according to GOST 21920. Corrosion studies were carried out on the installation described in clause 4.5.2. GOST 28084-89, with temperature control 88 ⁺ 2 ^o C and exposure of the samples 336 hours;
Rubber swelling was determined by the hydrostatic volumetric method according to GOST 9.030, section 1 and according to 4.7. GOST 28084-89. Moreover, the research used the rubber products used in the cooling systems of internal combustion engines of passenger cars of the Zhiguli type:
a) rubber-fabric hose TU 38-105-262-71;
b) a hose without a tissue layer TU 38-105-262-71;
c) rubber seals of the crane TU 38-105-250-71.

In the experiments in the preparation of samples of the coolant were used:
concentrated ethylene glycol without additives according to GOST 19710;
sodium tetraborate (borax) according to GOST 8429-77, grade 1, grade B;
1,2,3-benzotriazole, pure according to GOST 62-09-1291-87;
distilled water GOST 6709-72;
when preparing the prototype sample, the sodium salt of an aliphatic monobasic acid, C ₆ -sodium caproic acid according to TU 6-09-14-1899-75, was used as an organic additive;
high-boiling fractions M-2 according to TU 6-14-10-210-87 from technical batches; specific compositions of "High-boiling fractions M-2" used in the preparation of samples of the proposed coolant are shown in table. 1.

 In the table. 2 shows specific examples of the compositions of the samples of the proposed coolant with limit and average values of the ingredients. At the same time, each sample of the coolant (N 1-3 in Table 2) was prepared in three versions, differing among themselves with the samples of "High-boiling fractions M-2" (Table 1).

 In the table. 3 shows the specific cooking modes indicated in the table. 2 samples of the proposed coolant. The number of loaded ingredients is given based on the preparation of 1 kg of each sample of the proposed coolant.

 The initial input of sodium tetraborate and "High boiling fractions M-2" in the examples of the table. 3 in water due to the fact that 50% wt. sodium tetraborate (determined by potentiometric method) chemically interacts with the components of the "High-boiling fractions M-2" with the formation of complex compounds (due to the complexity of the composition of the "High-boiling fractions M-2" and the resulting complexes, it is impossible to identify the above complex formed by the available research methods). It is a mixture of "High-boiling fractions M-2" (50% by weight of the added amount) and the resulting complexes that determines to a greater extent the achievement of the objective of the invention: ensuring the corrosion inertness of the proposed coolant to the basic structural materials of cooling systems of internal combustion engines.

 Ethylene glycol is then introduced into the mixture of sodium tetraborate, high boiling fractions of M-2 and the products of their interaction. This sequence of ethylene glycol administration is due to the limited solubility of benzotriazole in water and its good solubility in ethylene glycol or an aqueous solution of ethylene glycol, i.e. without the preliminary introduction of ethylene glycol, a practically predetermined amount of benzotriazole cannot be completely dissolved in an aqueous solution of the previously introduced reagents.

 As a consequence of what was said in the previous paragraph, the benzotriazole is added during preparation, after which the whole mixture is stirred for 15 to 20 minutes. After mixing at the specified time, the resulting mixture is ready for use as intended as a coolant for cooling systems of internal combustion engines.

 In the table. 4 shows the main physico-chemical parameters of the samples of the proposed coolant specific modes of their preparation (table. 3), the prototype and the regulatory requirements for low-freezing coolants, defined by GOST 28084-89. Moreover, when evaluating the physicochemical parameters of the prototype (US patent N 4759864), a prototype sample was used in the studies with the following ingredients, mass.

Ethylene glycol 60.00
Sodium tetraborate 1.50
Benzotriazole 0.20
Sodium caproic acid (sodium salt of aliphatic monobasic acid C ₆ 1.60
Water up to 100.00
Of the presented in table. 4 data that the proposed coolant:
it is inert in relation to steel, cast iron, aluminum and solder, in relation to copper and brass 5.0 7.3 times less active than the known coolant (prototype);
not foaming;
swelling of rubber products is 4.8 times less than in the known coolant;
It has improved environmental characteristics: it does not contain nitrites, nitrates, benzoates, molybdates, phosphates, which are constant components in most known coolants and which are allowed in the compositions of US patent N 4759864;
has a crystallization onset temperature of minus 53 70 ^o C and is practically suitable for use in all areas, including the Far North.

 For the production of the proposed coolant, the technical documentation has been approved in the established manner and is being installed at the industrial site of PKF KAZAN LLP (Nizhnekamsk) a production facility of 10 thousand tons proposed coolant.

Claims (1)

 Coolant for internal combustion engines containing ethylene glycol, benzotriazole, sodium tetraborate, an organic additive and water, characterized in that it contains high boiling fractions M-2 as an organic additive, a mixture of by-products of the stage of separation of morpholine rectified from catalysis from the production of morpholine from diethylene glycol and ammonia in the following ratio of ingredients, wt. Ethylene glycol 54.50 65.50
Sodium tetraborate 0.10 0.30
Benzotriazole 0.35 1.00
High boiling fractions M-2 0.50 0.70
Water Else

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