RU2689420C1 - Method of manufacturing a marker of fuels and lubricants - Google Patents

Abstract

FIELD: manufacturing technology.SUBSTANCE: invention describes a method for making a marker for fuels and lubricants by adding a concentrate to mineral motor oil, characterized in that preparation of the concentrate is carried out by adding CNM "Taunit-M" into mineral motor oil, followed by stirring in mixer for 1 hour, field of which solution is subjected to ultrasound dispersion for 1 hour at frequency 22 kHz and power 1 kW, after which surfactant "Suprotec" is added to solution and mixed in mixer for 30 minutes.EFFECT: reduction of anti-wear properties, providing sedimentation stability, invisibility of marking and complete combustion of fuel due to availability of nanocarbon material.1 cl, 5 dwg, 3 ex

Description

The invention relates to a method for producing a marker concentrate containing carbon nanomaterials (CNM) dispersed in fuels and lubricants (POL).

Prior art

It is often necessary to identify a source of liquid hydrocarbon, such as oil, ligroin, gasoline, diesel fuel, jet fuel, kerosene, lubricants, gas, liquefied gas, etc. This need arises, for example, in cases of suspected fraud, such as theft from pipelines, tankers or storage facilities; intentional or unintentional deterioration of quality, dilution, mixing of fluid from different sources, in case of spills or leakage of oil from an unspecified source into the ground or into water, etc. The high cost and also tax evasion provide profitability, which greatly stimulates malicious actions against fluids. By proactively labeling liquids that are vulnerable to counterfeit liquids, it is possible to determine subsequently whether the original quality of the fluid remains or has been tampered with, diluted or damaged.

There are various compositions for the labeling of petroleum products, as well as methods for the preparation of markers of various substances.

Known fluorescent marker for petroleum products (Patent RF №2149887, IPC C10L 1/00, C10M 171/00, C10L 1/18, G01N 33/22, publ. 2000), containing a composition comprising the oil and the amount of marker, and as the marker is a compound selected from the group of the general formula (I) or (II), where R ₁ is a C ₁ -C ₁₈ alkyl group or aryl group, R ₂ , R ₃ , R ₄ and R ₅ is hydrogen, chlorine, bromine or C ₁ -C ₁₂ -alkyl and R ₆ - hydrogen, chloro or bromo, said token acquires color and fluorescence in contact with the developing reagent that converts the marker into the dia ion. The technical solution provides markers that are invisible in liquid petroleum products, but exhibit distinct fluorescence and / or colouration of the petroleum product in the presence of an appropriate reagent. In addition, the present invention also relates to a method for identifying a liquid petroleum product, which includes (a) obtaining a sample of a liquid petroleum product containing a detectable amount of the marker described above, and (b) adding an appropriate reagent to this sample to obtain fluorescence

A common significant feature of the considered and proposed technical solution is a composition using an invisible marker in the composition of the oil product.

The disadvantage of this composition is the impossibility of its use for petroleum products with high viscosity.

A known composition comprising an oil product and a marker, a method and solution for marking an oil product, a method for identifying an oil product, and a method for producing a marker (RF Patent No. 2218381, IPC C10L 1/00, C10M 159/02, C10N 30:20, 2003), consisting of the oil product and a colorless thymolphthalein marker, as well as a method of labeling petroleum products using this marker. The invention also relates to methods for identifying petroleum products using solutions containing said marker. Thymolphthalein marker is introduced into the composition of the marking solution or composition, being previously dissolved in a non-aqueous solvent that can dissolve in the marked oil product. The non-aqueous solvent is preferably selected from the group consisting of aromatic hydrocarbons, aromatic alcohols and aprotic solvents, and contains by weight about 5-50% (for example, 15-25%) marker and about 50-95% (for example, 75-85%) solvent. The invention provides for the creation of labeling solutions that are invisible in oil-based liquid products at an effective level of concentration, but acquire a distinctive blue color, being “developed” in the labeled product with the help of an appropriate developing reagent. The reagents used for the development of color are easy to handle and dispose of.

Common essential features of the considered and proposed method are the use of invisible markers, the development of methods for marking petroleum products.

The disadvantage is that the developing reagent can affect the technical characteristics of petroleum products.

In US patent No. 6312958, IPC G01N 21/17, 2000, a method for marking liquids with at least two marking substances and a method for detecting them is disclosed, with the result that the forged liquid is detected even if this forged liquid is marked with markers similar to the original markers. This patent uses at least two markers with overlapping absorption ranges, which allows the use of a large number of markers in a given wavelength range. The compounds used to distort the original fluid should have not only absorption limits similar to the original markers, but also characteristics similar to the original markers in the rest of the absorption range. Each deception marker can have only one relatively narrow absorption maximum corresponding to the maximum of the original markers. If light sources are used to emit only in the areas of absorption maxima, similar fluorescence spectra are likely to appear in both cases. But if light sources are used that emit radiation at a wavelength at which counterfeit markers have no absorption, but on which the original markers have overlapping absorption limits, then the fluorescent radiation emitted by these markers is detected in the case of the original markers, but not in the case of fake markers.

The disadvantage of this method of marking is the difficulty of preparing the original markers, taking into account the characteristics of light sources.

There is also known a method for producing a marker (US Pat. Of the Russian Federation No. 2218381, IPC C10L 1/00, C10M 159/02, C10N 30:20, 2003). The solution for marking petroleum products contains a marker and a solvent that is mixed with petroleum products. A biological pigment preparation, prodigiosin, in an amount of 0.13-2.20% is taken as a marker. The solvent used is ethyl alcohol, petroleum ether, ethyl acetate. The method of obtaining the marker includes the cultivation of Serratia marcescens bacteria on an oatmeal agar medium and the extraction with ethanol of 96% concentration with shaking. Extraction of bacteria with ethyl alcohol is carried out repeatedly until the bleaching of the bacterial mass, and after each treatment, the bacterial mass is precipitated and then separated from the supernatant.

The invention allows to create a highly effective tool using environmentally friendly natural pigment, to expand the range of markers used for marking petroleum products.

The known solution is characterized by increased complexity associated with conducting biotechnological processes in the manufacture of the marker.

In US patent No. 5980593, IPC C10L 1/18, C09D 5/00, C09D 11/00, C07D 11/02, 1999, disclosed a method for marking a liquid product with a group of markers and a method for identifying a liquid product. The marker is a compound synthesized by esterification, the corresponding linear or branched C ₁ -C ₁₈ alkylcarboxylic acid. According to this method, C ₅ -C ₁₀ alkylcarboxylic acids are used for fuel labeling, due to reduced interference from background fluorescence. The concentration of the marker in the liquid petroleum product is usually at least 0.25 parts per million (ppm).

The marker can be isolated from the labeled oil with a solution consisting of 5-60% by volume of water-miscible, oil-immiscible solvent-bridge, water, an alkaline mineral source, such as KOH, and / or alkyl- or alcocosiamine. To determine in situ, the appropriate volume of aqueous exuded mixture is mixed with the corresponding volume of the liquid oil being tested. If the marker is present in liquid oil, it will be highlighted with an aqueous layer and will fluoresce when it reacts with the mixture that is emitted. For high-quality detection of the marker using a manual source of UV radiation. According to this method, it is possible to determine the levels of the marker to approximately 5%. For example, the fuel was marked with a marker in the amount of 3 ppm dissolved in isooctane. The marker was isolated and tested under an ultraviolet lamp and gave a fluorescent light, indicating the presence of the marker.

The disadvantage of this method of marking is the use of a special solution to extract the marking substance from the oil product for subsequent detection by UV radiation, which greatly complicates the identification process.

Known lubricating composition and method of its preparation (US Pat. Of the Russian Federation. 2574585, С10М 125/18, С10М 125/02, B82Y 30/00, 2014), which contains a lubricating fluid and dispersed, in this liquid, graphite nanoparticles. Moreover, the content of graphite nanoparticles having an average thickness of less than 5 nm in the lubricating fluid is from 0.001 to 0.01 wt. % by weight of the lubricant, and which are represented by plates of fluorinated graphene containing from 8.98 to 13.84 at. % fluorine.

Although nano-inclusions in the composition of graphite and graphene lubricants make it possible to create cost-effective lubricating compositions that have excellent friction reduction properties, enhanced anti-wear properties and improved sedimentation stability, the disadvantage of such compositions is the impossibility of identifying oil products by graphite and graphene.

The closest to the claimed invention according to the method is a chemical marker (US Pat. No. 2199574, IPC C10L 1/00, C10M 171/00, C07C 9/22, G01N 33/00, 2003) containing n-alkanes C16-C26 or their mixtures, introduced into the composition of the marked substances (chemicals or mixtures thereof, diesel fuel, kerosene, paraffins of various grades, vaseline, anticorrosive compounds, cosmetics or drugs, etc.) or the preparation of compositions containing a chemical marker that are applied to product packaging, are introduced into adhesive compositions and other components of the product. A feature of the above-mentioned chemical marker is the possibility of its use for marking complex mixtures of organic compounds, for example, petroleum products. This is explained by the fact that the relative content of normal saturated hydrocarbons in petroleum products, in the production scheme of which distillation is usually present, is close to the normal Gaussian distribution. The introduction of the proposed chemical marker of a certain composition violates the Gaussian distribution of alkanes in the oil product and the ratio of the individual components of the mixture becomes atypical (anomalous), which is clearly seen in the study of mixtures by capillary gas-liquid chromatography. As a chemical marker, you can use one individual alkane for labeling simple substances or a mixture of 2-3 alkanes containing C16-C26. The use of n-alkanes C16-C26 as a chemical marker for substances, materials and products is not described in the literature. The introduction of a larger amount of these hydrocarbons as a chemical marker increases the number of abnormal peaks in the chromatogram, which increases the reliability of the determination of labeled substances, materials and products.

Common essential features of the prototype method and the claimed invention is the use of chemical substances that are invisible in the composition of the material being marked, as well as the use of hardware identification of the marker in the composition of the substance.

The disadvantage of the prototype method is the high cost of the components (H-alkanes C18-C26), which is 2 mln p / kg, which makes it impossible to use them in industrial production.

Tasks solved by the invention.

The present invention is directed to:

- the creation of a cost-effective marker-containing composition, which, when used in lubricants, further reduces friction and anti-wear properties and provides sedimentation stability;

- when marking fuels to ensure the invisibility of marking, more complete combustion of fuel due to the presence of nanocarbon material;

- exclusion of the possibility of counterfeiting a substance - a marker and the possibility of detecting dilution with unmarked petroleum products;

- the creation of a method of manufacturing a marker by preparing a stable suspension;

- high resolution marker identification

The essence of the invention.

The above objectives are achieved in a composition comprising an oil product and a detectable amount of a marker, while the marker contains a suspension of carbon nanomaterial (CNM) and surface-active substances (surfactants).

Suspension of CNM as a solid dispersed phase may contain carbon nanomaterial "Taunit - M", and as a liquid dispersed medium - liquid hydrocarbons.

Marked oil may contain a marker in a concentration of 10 _-4 wt. %

Suspension CNM as a solid dispersed phase may contain functionalized carbon nanomaterial.

The above objectives are achieved by the method of manufacturing a marker by adding labeled substances to the composition, by preparing a suspension by introducing a CNM into the liquid dispersion medium, followed by stirring for 1 hour, after which it is dispersed using ultrasound for 1 hour at a frequency of 22 kHz and a power of 1 kW followed by the introduction of surfactants followed by dispersion.

Industrial oil I-20A can be used as a dispersion medium and as a labeled oil product.

As a marked oil product, Litol-24 grease can be used, into which Taunit-M UNM and polyvinylpyrrolidone (PVP) in the amount of 10 _-4 wt. %, turn on the preheater and heat the sample to 60 ° C, maintain this temperature for 10 minutes and stir the solution for 1 h, then leave the resulting mixture until it cools completely in calm air.

The identification of the petroleum product can be carried out on an atomic absorption spectrometer MGA-915MD, for which the sample is introduced into the Kalosha gasoline for entry into the atomizer of the device.

When identifying oil for automatic correction of non-selective absorption, the Zeeman modulation polarization spectrometry method with high-frequency modulation can be used.

The implementation of the composition, including oil and the determined amount of the marker, while the marker contains a suspension of carbon nanomaterial (CNM) provides:

- the possibility of marking oil products with an invisible marker that is stable and does not decompose when interacting with oil products and environmental substances (for example, water);

- Suspended carbon nanomaterial allows to reduce wear of friction pairs when marking lubricants and to provide more complete combustion when marking combustible materials;

- to simplify the process of marking and identification of petroleum products.

The use of a suspension of CNM as a solid dispersed phase in the form of a carbon nanomaterial "Taunit - M", and as a liquid disperse medium - liquid hydrocarbons provides:

- the possibility of using industrially manufactured CNM with standard properties;

- due to the fixed ratio of the sizes of nanotubes of the same brand (batch), counterfeit marking material is excluded;

- use as a liquid dispersion medium - liquid hydrocarbons allows you to label solid and consistent lubricants by mixing them under heating to the melting temperature.

Use for marking the marker in a concentration of 10 _-4 wt. % provides reduced material costs.

The use of functionalized carbon nanomaterial in suspension of CNM eliminates the agglomeration of CNM during the preparation of the suspension.

The introduction of surfactants into the suspension prevents the sedimentation of CNM.

The manufacture of the marker by preparing a suspension by introducing a CNM into the liquid dispersion medium, followed by stirring for 1 hour, after which it is dispersed using ultrasound for 1 hour at a frequency of 22 kHz and a power of 1 kW, after which the surfactants are injected subsequent dispersion provides:

- simplicity of the technological process and the possibility of control;

- the possibility of preparing a permanent marker for the labeling of various types of petroleum products;

the use of a minimum amount of equipment for the labeling of petroleum products, which reduces capital costs.

The use of I-20A industrial oil as a dispersion medium and as a marked oil product provides a minimum range of materials for the preparation of the marker.

The use of Litol-24 lubricant, with the Taunit-M CNM and polyvinylpyrrolidone (PVP) as a marked oil product, heated the material to 60 ° C, keeping this temperature for 10 minutes and stirring the solution for 1 hour, followed by cooled to full cooling in air provides marking of greases.

Thus, the preparation of a concentrate of a marker consisting of motor oil and CNM consists of thorough mixing in a mixer (1 hour) and processing on an ultrasonic generator for 1 hour with a frequency of 22 kHz and a power of 1 kW. To preserve the steady-state suspension, surface-active substances (surfactants) are introduced into the ready-made solution and they are redispersed on an ultrasonic generator for 1 hour. Then the marker is introduced into the marked product by stirring on a mixer. As a surfactant, it is preferable to use the tribotechnical composition - additive "Suprotec". Tribotechnical composition is designed to protect against wear and maintain the performance of gasoline and gas engines of passenger cars, high pressure fuel pumps (high pressure fuel pumps), power steering pumps (GUR), gearboxes (PPC), etc. Use of this product in the concentrate concentrate allows you to prevent the deposition of CNM as much as possible, which significantly affects its distribution in the composition of the labeled fuels and lubricants. The concentration of CNM in the composition of the concentrate marker is 1%. CNM in the composition of the marked substance is not visually detected, since the concentration of the marker in the oil is 1 ppm. Identification of the nanomarker is carried out using the method of atomic absorption spectrometry with Zeeman correction of non-selective absorption, the use of which allows to determine the quantitative content of the marker.

The test results and the characteristics of the products used are shown in graphic materials, which depict:

- in fig. 1 — Taunit-M particle size distribution of batch E-260.143C.05;

- in fig. 2 shows a table of correspondence of particle sizes (D, μm) to given values of the weight fraction;

- in fig. 3 shows a table of the weight fraction of particles (P%) corresponding to the specified particle size values;

- in fig. 4 shows the results of three measurements of Rosneft SAE 10W-40 mineral engine oil;

- in fig. 5 - shows the content of the CNM "Taunit-M" in the marked and unmarked engine oil Rosneft SAE 10W-40.

The following are examples that prove the possibility of the proposed method and its effectiveness.

Example 1

For the manufacture of the suspension, the UNM Taunit-M of the batch E-260.143C.05 was used. The dimensions of this CNM are determined by the MicroSizer 201 laser particle size analyzer and are indicated in FIG. 1. As an oil product undergoing labeling, Rosneft SAE 10W-40 mineral engine oil is used, the characteristics of which are shown in FIG. 4. This oil is widely used in engineering, as a material used to create the anti-friction effect that occurs between parts of motors, gearboxes, etc. In a glass cup with a volume of 150 ml, equipped with a mechanical stirrer, load 100 g of Rosneft mineral oil of the SAE 10W brand -40, 1 g of CNM "Taunit-M" brand E.260.143.C, turn on the stirrer and mix the solution for 1 hour, then process the resulting solution on an ultrasonic generator for 1 hour, frequency 22 kHz, power 1 kW. After that, “Suprotec” (surfactant) 1 g is added to the ready solution and stirred on a mixer for 30 minutes. The resulting solution is considered a marker concentrate for motor oil.

To improve efficiency and ensure the invisibility of the marker, the concentrate prepared earlier is diluted in Rosneft SAE 10W-40 mineral engine oil to a concentration of 10 _-4 wt. %

The identification of the obtained labeled oil is carried out on an MGA-915MD atomic absorption spectrometer.

Result: in the marked mineral oil Rosneft SAE 10W-40, the mass content of Co in 20 µl of the sample was 49 pg, and the concentration was 2.4 µg / l.

The identification report, as well as the comparison chart of the content of the marker in the engine oil with the content of the marker in the commercial engine oil with the content of the marker in the marked engine oil, are presented in figures 2, 3, 5.

Example 2

For the manufacture of a suspension, the same CNM was used as in example 1. Industrial oil I-20A was used as a petroleum product undergoing labeling. It is intended for use as working fluids in hydraulic systems of machine equipment, automatic lines, presses, it can also be used in light and medium loaded gears, slide and rolling guides of machines and in other mechanisms where specialized lubricants are not required. A 150 ml glass beaker, equipped with a mechanical stirrer, is charged with 100 g of I-20A industrial oil, 1 g of Taunit-M brand E.274.142C, 1 g of polyvinylpyrrolidone (PVP) and the mixer is stirred for 1 hour, then process the resulting solution on an ultrasonic generator for 1 hour, frequency 22 kHz, power 1 kW. The resulting solution is considered a marker concentrate for motor oil.

Then the resulting concentrate is diluted in industrial oil I-20A to a concentration of 10 _-4 wt. % (0.11 ppm), while the marker becomes invisible.

The identification of the obtained labeled oil is carried out on an MGA-915MD atomic absorption spectrometer.

Result: in labeled industrial oil I-20 A, the mass content of Co in 5 μl of the sample was 180 pg, and the concentration was 35 μg / l.

The identification report, as well as the comparison chart of the content of the marker in the engine oil with the content of the marker in the commercial engine oil with the content of the marker in the marked engine oil, are presented in figures 2, 3, 5.

Example 3

As the oil undergoing labeling, use the lubricant "Litol-24". The lubricant is intended for use in heavily loaded machine nodes. These include bearings, linkage mechanisms, chain transmissions, as well as places of contact between the parts with elevated temperatures. In a glass cup with a volume of 150 ml, equipped with a mechanical stirrer and heater, load 100 g of industrial oil I-20A, 0.11 mg / kg (0.11 ppm) of the CNM Taunit-M, 1 g of polyvinylpyrrolidone (PVP) turn on the heater and heat the sample to 60 ° C maintain this temperature for 10 minutes and mix the solution for 1 h, then leave the mixture until completely cooled in calm air. The resulting composition is considered marked.

Identification of the obtained labeled lubricant "Litol-24" is performed on an atomic absorption spectrometer MGA-915MD. The sample for introducing the device into the atomizer is diluted in “Kalosha” gasoline, thereby achieving the liquid state of the labeled “Litol-24”.

Result: in the “Litol-24” labeled lubricant, the mass content of Co in 5 μl of the sample was 30 pg, and the concentration was 6.3 μg / l.

The identification report, as well as the comparison chart of the content of the marker in the engine oil with the content of the marker in the commercial engine oil with the content of the marker in the marked engine oil, are presented in figures 2, 3, 5.

The invention provides for the labeling of a wide range of petroleum products and their identification.

Claims (1)

A method of manufacturing a marker for fuel and lubricants by introducing the concentrate into mineral engine oil, characterized in that the preparation of the concentrate is carried out by introducing Taunit-M into the mineral engine oil, followed by stirring in a mixer for 1 hour, after which the solution is dispersed using ultrasound for 1 h at a frequency of 22 kHz and a power of 1 kW, after which the surfactant “Suprotec” is introduced into the solution and stirred in a mixer for 30 minutes.

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