RU2451293C1 - Method of determining working capacity of lubricating oil - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: when implementing the method, samples of used oil are collected, divided into two portions; the first portion undergoes photometering; the light flux absorption factor is determined; the second portion of the sample having constant weight undergoes temperature control while stirring at temperature corresponding to the purpose of the oil for a constant period of time; photometric measurements are taken; the light flux absorption factor is determined; two curves of distribution of the sample amount versus the selected intervals of values of the light flux absorption factor are plotted, and the limiting value of the light flux absorption factor is determined from the point of intersection of the two curves, and the working capacity of the lubricating oil is determined from said limiting value; if the value of the light flux absorption factor is less than the limiting value, the oil is suitable for use, otherwise it is not suitable for use.

EFFECT: easier evaluation of the working capacity of lubricating oil.

1 tbl, 1 dwg

Description

The invention relates to a technology for evaluating the quality of liquid lubricants.

A known method for determining the performance of lubricating oils, which consists in the fact that the spent oil sample is subjected to centrifugation with the subsequent determination of the optical density of the obtained upper layer and, in relation to the initial optical density of the working oil, is judged on its performance (see ed. Certificate. USSR No. 930120, cl G01N 33/30, published in BI No. 19, 1982).

The closest in technical essence and the achieved result is a method for determining the performance of lubricating oils by centrifuging an oil sample followed by photometry, a working oil sample is taken, divided into three parts: the first part of the oil sample is used to determine the viscosity, the second part of the oil sample is centrifuged, followed by by photometry and determination of the absorption coefficient of the light flux of the centrifuged sample, a third of the oil sample is tested the thermal-oxidative stability for no more than 2 hours at a temperature corresponding to the base base of the lubricating oil, the absorption coefficient of the light flux and the viscosity of the oxidized sample are determined, and the performance of the lubricating oil is determined from the expression: P _p = (K _by -K _pc ] η _o / η , P _p is the coefficient of health of lubricating oil; K _by is the absorption coefficient of the light flux of the sample of oxidized oil; K _pc is the absorption coefficient of the light flux of the sample of working oil after centrifugation; η _o and η are the viscosity of the oxidized and initial samples of the working oil, respectively (RF patent No. 2222012, IPC G01N 33/30, publ. 2002).

The known method is characterized by high complexity in determining the performance of lubricating oils and is quite long.

The technical result of the invention is to reduce the complexity of evaluating the performance of lubricating oils, which will allow them to be used more efficiently and adjust the timing of replacement.

The problem for solving the technical result is achieved by the fact that in the method for determining the performance of lubricating oils by photometric analysis of oils and determining the absorption coefficient of the light flux, according to the invention, samples of used oils are taken, divided into two parts, the first part is subjected to photometry, the absorption coefficient of the light flux is determined , the second part of the sample of constant mass is subjected to temperature control, photometry, determine the absorption coefficient of the light flux, building two graphical dependences of the distribution of the number of samples on the selected intervals of the absorption coefficients of the light flux, and the point of intersection of the two dependence curves determines the limit value of the absorption coefficient of the light flux and determines the efficiency of the lubricating oil by its value, if the absorption coefficient of the light flux is less than the limit value, then the oil operable, and if greater than the limit value of the absorption coefficient of the light flux, then inoperative.

The drawing shows the dependence of the absorption coefficient of the light flux on the number of tested oil samples: curve 1 - dependence of the absorption coefficient of the light flux of the original waste oil samples; curve 2 - dependence of the absorption coefficient of the light flux of thermostated samples of used oils.

The method for determining the performance of lubricating oils is as follows.

Spent partially synthetic motor oils (20 pcs.) Are drained from the engines of cars. Oil samples are taken weighing 130 g, divided into two parts 30 and 100 grams. The first part of the oil sample (30 g) is photographed (the thickness of the photometric layer is 0.15 mm), the absorption coefficient of the light flux K _{p is} determined.

The second part of the constant weight sample (100 g) is thermostated in a glass beaker at atmospheric pressure at a constant temperature of 180 ° C with stirring with a glass stirrer with a rotation speed of 300 rpm for a constant time (3 hours), then the thermostated oil sample is photographed, the coefficient is determined absorption of a luminous flux To _{pt of} thermostated sample. The test results of the spent partially synthetic motor oils by the proposed method are shown in the table. According to the test results before and after thermostating, the range of changes in the absorption coefficient of the light flux is divided into intervals. In the range of values of the absorption coefficient of the light flux To _{p the} initial oil samples to 0.2 units samples No. 1-4 fall; from 0.2 to 0.3 units, samples No. 5-13; from 0.3 to 0.4 units, samples No. 14-18, from 0.4 to 0.5 units, samples No. 19, 20. In the range of values of the absorption coefficient of the light flux K _{pt of} thermostated oil samples to 0.3 units samples No. 1, 7 fall; from 0.3 to 0.4 units, samples No. 2, 4, 8-11, 13; from 0.4 to 0.5 units, samples No. 3, 6, 12, 14, 17; from 0.5 to 0.6 units, samples No. 5, 16, 18, 19; from 0.6 to 0.7 units, samples No. 15, 20. Then two graphical dependences of the distribution of the number of samples on the values of the absorption coefficient of the light flux falling within the accepted intervals are built, and the limiting value of the absorption coefficient of the light flux is determined from the intersection of the dependence curves , which amounted to K _{p pr} = 0.37 units, determine the efficiency of engine oil by its value, if the absorption coefficient of the light flux is less than the limit value, then the oil is efficient and merged ahead of schedule, and if more If the actual value of the absorption coefficient of the light flux is then inoperative.

According to the test results it is seen (see tab.) That the oil samples under No. 1-17 did not reach the limit value of K _{p ave} = 0.37 units. 85% of the studied oil samples are drained from the engines ahead of schedule and have a reserve in use. Oil samples under No. 18-20 exceeded the limit value of the coefficient K _{p pr} , i.e. the engines operated on unsuitable oil, which amounted to 15% of the number of tested oils. Thermostated samples numbered 1, 2, 7, 4, 13 did not exceed the limit value of the coefficient K _{p pr} , these samples of used oils are also merged ahead of schedule and have a reserve in application.

The application of the method allows to periodically monitor the status of the operating lubricating oils, with minimal complexity using only a photometric device, and increase the efficiency of their use.

Table Partially Synthetic Used Engine Oil Test Results No. p / p Brand of oil The absorption coefficient of the light flux of waste oils K _p To _p. K _{p t} one. BP Visco 3000 10W-40 SJ / CF 0.17 0.30 2. BP Visco 3000 10W-40 SJ / CF 0.17 0.32 3. Ravenol TSI 10W-40 SM / CF; 0.17 0.5 four. BP Visco 3000 10W-40 SJ / CF 0.19 0.35 5. Ravenol TSI 10W-40 SM / CF 0.22 0.53 6. Zic A Plus 10W-40SL / CF 0.23 0.43 7. Ravenol HCS 5W-40 SL / CF 0.24 0.30 8. THK Super 5W-40 SL / CF 0.24 0.39 9. ESSO Ultra 10W-40 SJ / CF 0.24 0.38 10. ESSO Ultra 10W-40 SJ / CF 0.24 0.39 eleven. Texaco Havoline Extra 10W-40 SJ / CF 0.25 0.38 12. Texaco Havoline Extra 10W-40 SJ / CF 0.27 0.50 13. Zic A Plus 10W-40 SL / CF 0.29 0.33 fourteen. ESSO Ultra 10W-40 SJ / CF 0.30 0.49 fifteen. BP Visco 3000 10W-40 SJ / CF 0.30 0.73 16. Texaco Havoline Extra 10W-40 SJ / CF 0.31 0.58 17. Texaco Havoline Extra 10W-40 SJ / CF 0.32 0.41 eighteen. Zic A Plus 10W-40SL / CF 0.39 0.59 19. Texaco Havoline Extra 10W-40 SJ / CF 0.41 0.60 twenty. Zic A Plus 5W-30 SL / CF 0.51 0.72

Claims (1)

A method for determining the performance of lubricating oils by photometric sampling of oils and determining the absorption coefficient of the light flux, characterized in that the samples of the used oils are taken, divided into two parts, the first part is subjected to photometry, the absorption coefficient of the light flux is determined, the second part of the constant mass sample is subjected to temperature control with stirring , photometry, determine the absorption coefficient of the light flux, build two graphical dependence of the distribution of the number of samples on The selected intervals of the values of the absorption coefficients of the light flux and the intersection point of the two dependence curves determine the limit value of the absorption coefficient of the light flux, and the magnitude of the efficiency of the lubricating oil is determined if the absorption coefficient of the light flux is less than the limit value, then the oil is operational, and if it is greater than the limit value light absorption coefficient is then inoperative.

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