RU2298173C1 - Method of oxidation stability testing of lubricants - Google Patents

Abstract

FIELD: measuring technique.

SUBSTANCE: method comprises testing two samples of the lubricant of the same mass, the first sample being tested without catalyzer and the second sample being tested in the presence of catalyzer, determining transparency coefficient by means of photometric measurements, plotting time dependences of the transparency coefficient, and determining oxidation stability of the lubricant from the equation presented.

EFFECT: enhanced precision.

3 dwg, 1 tbl

Description

The invention relates to tests of lubricating oils and can be used in laboratories in the study of the influence of metals on the oxidative processes occurring in lubricants, to determine the catalytic activity.

A known method for determining the thermo-oxidative stability of lubricants (RF patent No. 2057326, IPC G01N 25/02, publ. 03/27/96), which consists in heating the oil in the presence of air, mixing and determining parameters for evaluating the oxidation process. Two samples of the lubricant are tested. The optical density of the samples of the initial lubricant is determined by photometric preliminary, then the first sample is heated simultaneously with stirring to a certain temperature, kept at a given temperature for a time interval at the end of which the optical density is determined, after which the temperature is sequentially increased with the selected step, the sample is held at each temperature value during the interval at the end of which the optical density is determined and a graphical dependence of density at temperature, at the inflection point of which the temperature of the onset of oxidation is determined, then the second sample is heated to a temperature higher than the temperature of the onset of oxidation, maintained at the achieved temperature and the optical density is determined at selected time intervals, and a graphical relationship of the optical density of the oxidized lubricant to the optical density of the initial lubricant from the time of oxidation and the tangent of the angle of inclination of the abscissa axis in the area to the point and the kink of the line determines the rate of formation of soluble oxidation products, and the tangent of the slope of the line determines the rate of formation of insoluble oxidation products.

The closest in technical essence and the achieved result is a method for determining the thermo-oxidative stability of lubricants (RF patent 2219530, IPC G01N 25/02, publ. 12/20/2003), which consists in the fact that the lubricant is heated in the presence of air, mixed, photometric and determined parameters for evaluating the oxidation process. A constant volume lubricant sample is tested at an optimum temperature selected depending on the base base of the lubricant and the group of operational properties over a period of time characterizing the same oxidation state, and at regular intervals, an oxidized lubricant sample is taken, the absorption coefficient of the light flux by an oxidized lubricant is determined by photometry material, build a graphical dependence of the change in the absorption coefficient of the light flux on time Test prolong line depending after the inflection point until it intersects with the abscissa axis and the abscissa of the points determine the start time of insoluble impurities from the inflection point depending determine the start time of coagulation of insolubles, but in the limit value of the absorption coefficient of the luminous flux is determined resource lubricant performance.

A disadvantage of the known technical solutions is the low information content of indicators about the progress of oxidation processes in time and the resulting oxidation products.

The basis of the invention is the task of determining the thermo-oxidative stability of lubricants in the presence of catalysts, which increase the information content and accuracy of evaluating the thermo-oxidative stability of lubricants by obtaining additional information about the onset of the catalytic activity of metals and quantifying the change in thermo-oxidative stability from the action of the catalyst, i.e. energy absorbed by the test medium, the result of which are the products of oxidation and the destruction of the base base and additives.

The problem is solved in that in the method for determining the thermo-oxidative stability of lubricants, including heating the lubricant in the presence of air, mixing, sampling the oxidized lubricant, photometry and determining the parameters of the oxidation process by graphical dependencies, according to the invention, two samples of constant mass lubricant are tested separately , the first without a catalyst, the second with a catalyst at the same temperature for a set time, m at regular intervals, a sample of the oxidized lubricant is taken, photometric transmission coefficient of the light flux K _pr is determined without using a catalyst and with it, graphical dependences of the change in the transmission coefficient of the light flux of the oxidized lubricant on the test time are constructed and the beginning of the catalytic effect of the catalyst is determined by its time and value and thermo-oxidative stability of lubricants determined coefficient of catalytic metals on the action of K _KD expr zheniyu:

K _cd = S / S _k ,

where S is the area of the curve of the dependence of the transmittance of the light flux on the test time of the lubricant without catalyst, mm ² ,

S _to - the area of the curve of the dependence of the transmittance of the light flux from the test time of the lubricant with the catalyst, mm ² .

A comparative analysis of the prototype and the proposed method showed that the latter has the following distinctive features.

Determination of the coefficient of catalytic effect on thermo-oxidative stability K _Kd as the ratio of the areas of the curves of the dependences of the test of the lubricant [K _ol = ƒ (t)], characterizing the thermal energy absorbed, respectively, when testing the lubricant without a catalyst and with it, for the accepted period of time, allows you to evaluate the activity of the catalytic effect of metals.

The construction of graphical dependences of the change in the transmittance of the light flux of the test lubricant on the test time allows you to visualize the oxidation kinetics and determine the time parameters characterizing the catalytic effect on the thermo-oxidative stability of lubricants: the beginning of the catalytic effect of the catalyst; the area of the curves of the dependences of the transmittance of the light flux on the test time of the lubricant with and without catalysts; coefficient of catalytic effect on thermo-oxidative stability. All these accepted indicators are aimed at solving the problem - improving the accuracy and reliability of the thermo-oxidative stability of lubricants by obtaining additional information about the manifestation of the onset of catalytic activity of metals and the coefficient of catalytic effect on the thermo-oxidative stability of lubricants.

Figure 1 shows the dependence of the transmittance of the light flux on the test time of mineral oil without catalysts and with them; figure 2 - dependence of the transmittance of the light flux from the test time of a partially synthetic oil; figure 3 - dependence of the transmittance of the light flux from the test time of synthetic oil.

The method for determining the thermal oxidative stability of lubricants is as follows.

A glass cup with a test oil without catalyst weighing 100 g is installed in a cylindrical furnace of the apparatus for determining thermal oxidative stability, heated to an optimum temperature, for example 180 ° C, with an accuracy of ± 2 ° C and mixed with air using a mechanical device. In the test process, a sample of lubricants is taken every 2 hours, photometric and thermo-oxidative stability is determined by the transmittance of the light flux from the expression K _CR = P / 300, where P is the photometer during photometric testing of the test sample of lubricant, μA; 300 - indicator of the photometer in the absence of oil in the photometric cell, μA. In parallel, the same thing is done with the same oil with a catalyst as metal samples. To study the effect of metals and the base lubricant base, motor oils were selected on mineral (M-6 _s / 10-V), partially synthetic (Sibi Motor 10W-40 SJ / CD) and synthetic (Mannol 5W-40 SJ / CF) bases . Steel 3 (GOST 380-71), copper M1 (GOST 495-77) and ШХ15 steel (GOST 801-60), which are disks with a diameter of 40 mm and a thickness of 2 mm, were chosen as metal samples. The surface of the samples was polished, and before testing, degreased with A-80 gasoline.

According to the test results, graphical dependences of the transmittance of the light flux of the oxidized lubricant on the test time are constructed [K _ol = ƒ (t)]. These dependences have inflection points O ₁ , O ₂ , O ₃ , which characterize the beginning of the catalytic activity of metals on the oxidation of oils. The slower the metals contribute to the oxidation of oils and the transmittance of the light flux is lower, the better the thermal oxidative stability of the oils. The coordinates of the points O ₁ , O ₂ , O ₃ show the onset of the action of the catalysts, after which the catalytic activity of metals reduces the thermal oxidative stability.

The influence of metal catalysts on the mechanism of oxidation of lubricants was estimated by a coefficient characterizing the catalytic effect on thermo-oxidative stability K _cd and determined by the ratio of the areas of the curve of the dependence K _pr = ƒ (t) of the lubricant without catalyst and with it. By considering the graphical dependence K _CR = ƒ (t) it was found that copper exhibits a more active catalytic effect. For a quantitative assessment of the catalytic effect of metals on oxidative processes in lubricants, a coefficient of catalytic action is proposed, determined from the expression:

K _cd = S / S _k ,

where S is the area of the curve of the dependence of the transmittance of the light flux on the test time of the lubricant without catalyst, mm ² ,

S _to - the area of the curve of the dependence of the transmittance of the light flux from the test time of the lubricant with the catalyst, mm ² .

A characteristic feature of the obtained dependences is that the effect of the catalysts on oxidation is determined by the change in K _cd . The higher K _cd , the greater the influence the catalyst has on oxidative processes. As a result of research on mineral oil (figure 1) it was found that the change in thermal oxidative stability depends on the base oil and the type of metal catalyst, the effect of which is established by finding the coefficient of catalytic action on thermal oxidative stability.

The results of the analysis of mineral (figure 1), partially synthetic (figure 2) and synthetic (figure 3) lubricants are tabulated according to the proposed indicators characterizing the catalytic effect of metals on the thermo-oxidative stability of lubricants. These indicators include: the start time of the catalytic action of the catalyst; the area of the curves of the dependences of the transmittance of the light flux on the test time of the lubricant with and without catalysts; coefficient of catalytic effect on thermo-oxidative stability.

Thermal-oxidative stability of mineral oils (Fig. 1) decreases when they are tested in the presence of catalysts, and the catalytic effect of steel St.3 occurs after 17 hours of testing, and steel ШХ15 and copper after two hours of testing and their intensity of oxidation processes is the same to 11.5 hours of testing, and then the dependency branches diverge. Copper has the greatest effect on oxidative processes, since the start time of the catalytic activity of metals is 11.5 hours, the area of the curve of the light transmittance versus time is 12.148, and the catalytic coefficient is the largest - 1.168.

Thermal oxidative stability of partially synthetic oil (figure 2) is increased in the presence of all investigated catalysts. A characteristic feature of the obtained dependences is that up to five hours of testing, metals have the same effect on oxidation processes, and after this test time they split into two branches: one branch is characterized by the influence of steel St.3 and copper, the other - steel ШХ15, and after 13 hours of testing, a branch departing from the first branch characterizing the effect of steel St.3 on oxidation processes, which has a more intense effect on oxidation. Compared to mineral oil, the studied catalysts have a lesser effect on the oxidation of partially synthetic oil and are oxidation inhibitors. Copper is the best inhibitor, since the start time of the catalytic activity of steel St.3 and copper is 2.0 hours, and that of ShKh-15 steel is 5 hours, the area of the curve of the light transmittance versus time is the largest - 8.586 and the catalytic coefficient is the smallest - 0.894.

The effect of the catalysts on the oxidation of synthetic oil (Fig. 3) is insignificant and manifests itself at the beginning of the test and takes place according to one dependence up to 6.6 hours of testing, and then it is bifurcated into two branches, the same effect of steel St.3 and copper is evaluated, and on the other - steel ШХ15. A more active catalytic effect is shown to decrease the thermal-oxidative stability of oil copper and steel Art. 3, since the start time of the catalytic effect was 6.6 hours, the curve area of the light transmittance was 17.659 and 17.68, and the catalytic coefficient was 1.046 and 1.045 .

Thus, the proposed method allows to increase the information content and accuracy of evaluating the thermo-oxidative stability of lubricants.

Table The name of indicators Example 1 Example 2 Example 3 mineral oil M-6 _s / 10-B partially synthetic motor oil Sibi Motor 10W-40 SJ / CD synthetic motor oil Mannol 5W-40 SJ / CF without catalysts catalysts without catalysts catalysts without catalysts catalysts + Cu + steel ШХ15 + St3 + Cu + steel ШХ15 + St3 + Cu + steel ШХ15 + St3 The start time of the catalytic action of the catalyst, hours - 11.5 16,2 17 - 2.0 5 2.0 - 6.6 11.8 6.6 The coefficient of catalytic effect on thermal oxidative stability one 1,168 1,068 1.015 one 0.894 0.949 0.907 one 1,046 1,026 1,045 The area of the curves of the dependences of the coefficient of thermo-oxidative stability on the time of testing oils, mm ² 14,195 12,148 13,295 13,985 7,677 8,586 8.09 8,459 18,473 17,659 18,015 17.68 Note: test time for mineral and synthetic oils is 20 hours; partially synthetic - 13 hours; test temperature 180 ° C

Claims (1)

A method for determining the thermo-oxidative stability of lubricants, including heating a lubricant in the presence of air, mixing, sampling an oxidized lubricant, photometry, determining the parameters of the oxidation process by a graphical dependence, characterized in that two samples of constant mass lubricant are tested separately, the first without a catalyst, the second with the catalyst at the same temperature for a set time, and at regular intervals taken a sample of oxidized lubricant, determine photometric transmittance of the light flux without catalyst and with it, build the graphical dependence of the transmittance of the light flux of oxidized lubricant on the test time and the time and value of the specified coefficient determine the onset of the catalytic effect of the catalyst, and the thermo-oxidative stability of the lubricants is determined the coefficient of catalytic action of metals To K _d expression K _cd = S / S _k , where S is the area bounded by the curve of the transmittance of the light flux from the test time of the lubricant without catalyst, mm ² , S _to - the area bounded by the curve of the transmittance of the light flux from the test time of the lubricant with the catalyst, mm ² .

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