UA102049U - METHOD OF CONTROL OF MOTOR OIL - Google Patents

Abstract

A method of controlling motor oil, according to which the sample of the lubricant is placed in the optical cell, is irradiated with a low power laser, and the characteristics of the lubricant is determined by the comparative physical characteristics of pure oil and lubricants with products of wear. Samples of the reference engine oil and the test oil are dissolved in concentrations of benzene reforming in concentrations (50-85 vol.%), After which the samples are placed on a sensitive element of the device based on surface plasmon resonance, irradiated at an angle greater than their angle of internal reflection, and the intensity of change of the index of surface plasmon resonance is recorded by a photodetector, and the wear characteristic of the motor oil is determined by the level of deviation of the angle of minimum of the surface plasmon resonance the test lubricant is compared to the reference lubricant.

Description

The proposed useful model belongs to the methods and devices for controlling the composition of substances, and can be used to control the contamination of engine oil at enterprises of the machine-building industry, aircraft construction, and scientific research in tribology.

There is a known method of monitoring the technical condition of machines and mechanisms |1|, according to which the studied technological liquid (lubricant) is passed through a magnetic field and capacitive sensors. The presence of magnetic particles in the process fluid and their ratio by mass is determined by measuring the ratio of the dielectric values of the lubricant with particles of magnetic impurities of greater mass and of the process fluid with particles of magnetic impurities of lower mass by measuring the electrical capacity of capacitive sensors installed in the liquid pipeline. At the same time, the ratio of the capacities of the sensors located in the flow of lubricant at different distances from the source of the magnetic field located on one side of the liquid pipeline is controlled. The evaluation of the technical condition of the machine is carried out by determining the magnitude and rate of deviation of the ratio of electrical capacities from the reference ones obtained for the non-working process fluid.

The method of operational control of lubricant performance has high informativeness and reliability of the conclusion about lubricant performance due to the fact that the diagnostic parameter "general pollution" is evaluated simultaneously in three spectral ranges, and additionally the diagnostic parameter "chemical destruction" is used, which characterizes the change in the chemical properties of the lubricant.

The disadvantage of the analogue is that the known method allows to selectively control the degree of wear of machines and mechanisms, but only in the presence of ferromagnetic particles of wear products. In addition, due to the aging of technological fluids, a false assessment of the state of wear is possible as a result of an increase in the dielectric characteristic of the technological fluid and the absence of a standard for comparison. This method involves the use for control of a large volume of samples of technological liquid, which is non-technological.

The closest method, taken as the closest analogue, is the method of analyzing the contamination of engine oil of an internal combustion engine with dispersed particles (21, according to which a sample of oil is placed in an optical cell, irradiated with low-power

With a laser and ultrasound, scattered and reflected radiation by dispersed particles is registered, for comparison, a reference channel with clean engine oil and two control channels in the examined volume of the engine crankcase are used. Based on the amplitudes and pulse durations of scattered signals on the photodetectors and the ratio between the signals of the reference channel and the metal particle control channel, as well as between the signals of the reference channel and the carbon particle control channel, the size of dispersed particles, the degree and nature of engine oil contamination are determined.

The method can be used for operational control of the concentration of mechanical impurities in motor oil, for example, wear products of machines and mechanisms in the oil, as well as for determining the concentration of insoluble combustion products in it.

The disadvantage of the closest analogue is the impossibility of controlling the degree of oxidation and general contamination of the motor oil, a high measurement error caused by the introduction of methodological errors of each method, and the temperature difference in the measuring and reference channel.

Thus, the closest analog method is not accurate enough.

The purpose of the proposed useful model is to increase the accuracy of motor oil control.

The task is solved by proposing a method of controlling motor lubricants, according to which a sample of lubricant is placed in an optical cell, irradiated with a low-power laser, and the characteristics of the lubricant are determined by the comparative physical characteristics of pure lubricant and lubricant with wear products, which differs in that the samples of the reference motor lubricants and lubricants under investigation are dissolved in the raffinate of benzene reforming in concentrations (50-85 06.95), after which the samples are placed on the sensitive element of the device based on surface plasmon resonance, they are irradiated at an angle greater than the angle of their total internal reflection, and the intensity of change the indicator of surface plasmon resonance is registered with a photo receiver, and the wear characteristic of the motor lubricant is determined by the level of deviation of the value of the angle of the minimum of the surface plasmon resonance of the lubricant, which is studied in comparison with the reference lubricant.

The PPR effect occurs when electromagnetic radiation of the visible range interacts with the separation boundary of two media. At the same time, a condition for the existence of a surface plasmon is the presence of a negative dielectric constant in one of the adjacent media in the working range. Since the dielectric constant for metals due to the plasma of free electrons is negative in a wide spectral range, the metal film (mainly A! or

Ad) on the dielectric substrate is the sensitive element of the PPR sensor.

The PPR phenomenon consists in a sharp decrease in the intensity of light reflected from the above separation boundary, which is observed at a specific wavelength and a specific angle of incidence.

In order to obtain a resonant PPR curve, you can either change the wavelength of the incident light at a fixed angle of incidence, or use monochromatic radiation to change the angle of incidence. At the same time, three methods are known for surface plasmon excitation using metallized IR diffraction gratings), a metallized glass prism (Krechman configuration) or a prism in close contact with a metallized glass substrate (Otto configuration). The shape of the resonance curve and the position of the minimum will be determined by the optical characteristics of the entire structure as a whole, including the medium in contact with the metal film on the opposite side. The claimed utility model uses the Kretschmann configuration.

The shape of the plasmon resonance curve and, in particular, the position of the minimum, depend on: the refractive index of the prism, the optical constants, and the thickness of the metal film in which the surface plasmon resonance is excited, and on the optical parameters and the thickness of the layer in contact with the metal working element. Fixing the change in resonance conditions for the occurrence of the plasmon effect, i.e. by examining the change in the position of the plasmon resonance minimum over time, it is possible to draw conclusions about the processes of adsorption and interaction of molecules occurring at the considered separation boundary and characterize them quantitatively. The results of measurements are mathematically processed according to a specially developed algorithm. Due to the mechanical sweep along the angle of incidence of radiation on the working element, the sensor provides a range along the angle of incidence of 17 angular degrees. This makes it possible to obtain a complete PPR curve and, with the help of special software, to calculate the optical constants and thicknesses of the layers included in the system. And also work with media that have refractive indices from 1.0 to 1.5.

With the help of PPR, it is possible to determine refractive indices with a sensitivity of 4x10 and an accuracy of 2x10, which cannot be achieved by electrical capacitive methods. In addition, the PPR method allows the use of very small samples of the investigated substance from 10 to 50 μl for analysis, which is technologically advantageous.

From Example of implementation.

To implement the proposed method, the method developed at the Institute of Semiconductor Physics named after V.S. Lashkaryova of the National Academy of Sciences of Ukraine two-channel device PLASMON-71 I4|. which works on the basis of the phenomenon of surface plasmon resonance (SPR). A semiconductor injection laser bZad5 with a wavelength of 850 nm is used as a radiation source. The accuracy of measuring the refractive index by the value of the angle of the PPR minimum by the PLASMON-71 device is x2x1075, and the sensitivity is 5x105. Motor oil was studied

MoBii Zireg 3000 5m/-30 in the condition of delivery (reference sample) and after a short (30 percent of the value recommended for replacement) vehicle mileage. Dilution up to 50 vol. 95 of lubricant causes a measurement error of 8x107 because the physical properties of the solvent, not the lubricant, dominate the sample. At concentrations of 50-85 006.95 lubricant, the physical characteristics of the lubricant dominate, the error is 4x105, and there is rapid deposition of wear products and impurities on the sensitive element. The use of the motor lubricant solution was carried out in concentrations greater than 85 o0vol.95 of lubricant, the error is 6х107, however, a slow deposition of wear products on the sensitive element is observed, which increases the measurement time. In repeated studies, it was found that the optimal option is 75 vol. 95 motor oil.

After dissolving in the declared range, the samples are stirred on the sensitive element of the device based on surface plasmon resonance. In the first measuring cell of the device

PLASMON-71 with a volume of 0.2 ml was placed as a reference motor oil, and in the second cell with a volume of 0.2 ml, the motor oil tested after the run was located. Both cells are irradiated with radiation at an angle greater than the angle of their total internal reflection, and the intensity of changes in the surface plasmon resonance indicator is recorded by a photodetector. The wear characteristics of the motor lubricant are determined by the level of deviation of the value of the minimum angle of the surface plasmon resonance of the lubricant, then it is studied in comparison with the reference lubricant, according to experimental studies.

During the conduct of similar studies on the closest analogue, the measurement error was 16x1075. The use of a device based on surface plasmon resonance with a pre-dilution operation made it possible: first, to increase the accuracy of the measurement by 2 times, as well as the measurement time due to the increase in the sedimentation rate of impurities, wear products and suspended particles on the sensitive element; secondly, shift the position of the PPR minimum to the zone of smaller angles, expanding the measurement range, which makes it possible to measure motor lubricants with a higher refractive index; thirdly, to increase the difference in PPR indicators of clean and contaminated lubricant, which allows control of pollution in the early stages.

The positive effect (usefulness) of the proposed technical solution consists in increasing the measurement accuracy by 2 times compared to the nearest analog.

Sources of information: 1. Khulla V.D., Kukoz F.Y., Khulla M.V., Kukoz V.F. The method of monitoring the technical condition of machines and mechanisms, patent RF Mo 2310187. publ. 2007. 2. Semenov V.V., Khanzhonkov Yu.B., Astaturov Yu.G. The method of analyzing the contamination of engine oil of an internal combustion engine with dispersed particles, RF patent Mo 2498269, publ. 2013. 3. N. Kaeshsheg "Z!ygase Royapop5", Eaz. Adgapomisy apa Miiv5, Moi NoiMapa Rybi. Sotr.,

Atvieegdat, 1982. 4. Yu.M. Shirshov, E.F. Wenger, A.V. Prokhorovich, Yu.V. Ushenin, S.P. Matsas, V.Y. Chegel,

A.V. Samoilov, A method of detecting and determining the concentration of biomolecules and molecular complexes and a device for its implementation; Patent of Ukraine number 46018, publ. 05/15/2002; Bull. Mo 5.

Claims (1)

USEFUL MODEL FORMULA A method of controlling motor oil, according to which a sample of oil is placed in an optical cell, irradiated with a low-power laser, and the characteristics of the oil are determined by comparing the physical characteristics of pure oil and oil with wear products, which differs in that the samples of the reference engine oil and the oil under investigation, dissolve in the raffinate of benzene reforming in concentrations (50-85 vol. 95), after which the samples are placed on the sensitive element of the device based on surface plasmon resonance, they are irradiated at an angle greater than the angle of their total internal reflection, and the intensity of changes in the surface plasmon resonance indicator are registered with a photo receiver, and the wear characteristic of the motor lubricant is determined by the level of deviation Зо of the value of the minimum angle of the surface plasmon resonance of the lubricant, which is studied in comparison with the reference lubricant. 0 Computer keyboard. Matselod 00000000 State Intellectual Property Service of Ukraine, st. Vasyl Lypkivskyi, 45, m. Kyiv, MSP, 03680, Ukraine SE "Ukrainian Institute of Intellectual Property", str. Glazunova, 1, m. Kyiv - 42, 01601