RU2368645C2 - Identification method of marked oil products - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method involves oil product sampling containing the detected number of token; at that, availability and quantitative content of token in the oil product is determined according to the availability of optical spectrum and intensity of spectrum lines in the wave-length region λ=350…600 nm without preliminary sample acidation and with the possibility of performing the flow analysis.

EFFECT: improving accuracy and fidelity, and simplifying identification process.

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Description

The invention relates to the field of the petrochemical industry and can be used to identify petroleum products marked with a biological marker-pigment prodigiosin.

It is known that oil products are labeled, for example, to control their quality or to prevent the sale of counterfeit (illegal) products.

Closest to the proposed is a method for identifying petroleum products labeled with a biological pigment prodigiosin [1].

A method for identifying an oil product [1] containing detectable amounts of a marker (prodigiosin) includes sampling an oil product, adding a developing reagent (36% hydrochloric acid) to the oil product and then quantifying the content of the marker in the oil, poured into a 1 cm thick cuvette by absorption spectroscopy , at a wavelength of optical radiation equal to λ = 535 nm.

The disadvantage of the prototype is that its use requires the use of a developing reagent. The need to use a developer complicates the process of identifying an oil product. A measurement of the absorption of the oil product at only one point, at a wavelength of λ = 535 nm, makes the identification not very accurate and unreliable, for example, due to the error of the analytical device. In addition, when a developing reagent is added to many petroleum products, for example, various brands of marked fuel, for example, AI-93, A-76 gasoline, diesel fuel, a fine precipitate is formed that does not transmit light rays and makes it impossible to determine the amount of optical absorption. The disadvantage of the prototype is also the inability to identify labeled oil without sampling, directly in the flow of a substance (oil).

The task of the invention is to increase the accuracy, reliability of the identification results and simplify the identification process of labeled petroleum products.

The problem is solved by the fact that a sample of the oil product, marked using a biological marker-pigment prodigiosin in a detectable amount, is taken. The sample is poured into the cuvette of the spectrophotometer and the optical absorption spectrum of the marker is recorded in the wavelength region λ = 350 ... 600 nm. The resulting spectrum is compared with the absorption spectrum of the marker in the specified area.

A labeled oil product, such as gasoline, demonstrates the presence of an absorption spectrum in the wavelength region λ = 350 ... 600 nm, which is characteristic of the absorption spectrum of a marker at a pH below 7.0. Moreover, by the degree of intensity of the spectral lines, comparing their intensity with the intensity of the known standard, determine the concentration of the marker in the test oil.

An unlabelled oil product under similar research conditions demonstrates the absence of an absorption spectrum in the wavelength region of λ = 350 ... 600 nm.

By the presence or absence of an absorption spectrum in the region of λ = 350 ... 600 nm, the intensities of the spectral lines determine the presence or absence of a marker. Legal petroleum products that meet accepted standards must be marked in a manner known to the manufacturer. And counterfeit oil products do not have such markings, or have a marker that does not meet the standards of the legal manufacturer of the oil product. By the presence of the marker, the intensity of its spectral lines, with an accuracy higher than that of the prototype, controls the compliance (or non-compliance) of petroleum products with standards or prevents the sale of illegal (counterfeit) products.

The prodigiosin marker in solution exists in one of two different but convertible forms, depending on the concentration of hydrogen ions in the medium [2]. In an acidic solution, the pigment has a red color, and its spectrum in the visible region of optical radiation is represented by a pointed, high, narrow main band, with a maximum at a wavelength of light λ = 535 ... 540 nm and a weak shoulder at λ = 510 nm. The shoulder is always present and does not depend on the purity of the sample. In an alkaline solution, the pigment is orange-yellow in color and has a spectrum represented by a wide, less intense (than in an acidic solution) symmetrical strip centered at λ = 470 nm [2].

The implementation of the proposed method is shown below the examples of labeling of petroleum products and their identification. The results are shown in Fig.1-15.

First, the dissolved concentrated marker prodigiosin is mixed with the oil so that the marker content in the oil corresponds to (1.20 ... 9.30) × 10 ^-6 g / l, i.e. (1.20 ... 9.30) multiplied by 10 minus sixth degree. So mark the studied petroleum product. Next, work with labeled petroleum products.

Example 1

0.13 g of the prodigiosin marker is dissolved in 100 ml of 96% ethanol. The dissolved marker is mixed with AI-98 gasoline to a final concentration of prodigiosin equal to 4.85 × 10 ^-6 g / l (0.250 optical units per ml), that is, gasoline is marked.

For identification purposes, 5 ml of labeled gasoline is taken, a sample is poured into the spectrophotometer cuvette, and the optical absorption spectrum of the marker in gasoline is measured in the wavelength range λ = 350 ... 600 nm, for example, on a uv / vis Spectrometr Lambda 35 recording spectrophotometer manufactured by Perkin Elmer instruments. For analysis, it is possible to use a recording spectrophotometer of any brand. The obtained spectrum of the marker in the test sample is compared with the absorption spectrum (Fig. 1) of the prodigiosin marker dissolved in acidified ethanol (9 ml of 96% ethanol + 1 ml of 1N HCl). On the horizontal axis of FIG. 1, wavelengths in nanometers (nm) are indicated, on the vertical axis, optical absorption units A (dimensionless quantity) are indicated.

Labeled gasoline demonstrates the presence of an absorption spectrum at λ = 350 ... 600 nm, characteristic of the absorption spectrum of the prodigiosin marker dissolved in acidified ethanol (Figure 3). Unmarked gasoline demonstrates the absence of an absorption spectrum in the region of λ = 350 ... 600 nm (Figure 2).

Example 2

Identification of the marker in gasoline is performed in a similar manner to Example 1, using AI-95 brand gas as an object of study. The result is in Figs. 4, 5.

Example 3. Identification of the marker in gasoline is performed in a similar manner to Example 1, using AI-92 grade gasoline as an object of study. The result is in Fig.6, 7.

Example 4. Identification of a marker in gasoline is performed in a similar manner to Example 1, using grade A-76 gasoline as an object of study. The result is in Figs. 8, 9.

Example 5. Identification of a marker in gasoline is carried out in a similar manner to Example 1, using aviation kerosene as a research object. The result is shown in FIGS. 10, 11.

Example 6. Identification of a marker in gasoline is performed in a similar manner to Example 1, using aviation gasoline of the AVYAS 100 LL brand as an object of study. The result is shown in FIGS. 12, 13.

Example 7. The identification of the marker in gasoline is performed in a similar manner to Example 1, using diesel fuel as an object of study. The result is shown in FIGS. 14, 15.

The method allows the use of a prodigiosin marker, dissolved in other solvents, for example ethyl acetate, petroleum ether. Perform this, for example, as follows.

0.13 g of the prodigiosin marker is dissolved in 100 ml of ethyl acetate or petroleum ether. The dissolved marker is mixed with the analyzed petroleum product, for example, AI-98 grade gasoline, to a final marker concentration of 4.85 × 10 ^-6 g / l (0.250 optical units per ml).

Example 8. Identification of a marker in gasoline is performed in a similar manner to Example 1, using a marker dissolved in ethyl acetate to mark the oil product.

Example 9. Identification of a marker in gasoline is performed in a similar manner to Example 1, using a marker dissolved in petroleum ether to mark the oil product.

As shown in the examples, in comparison with the prototype of the proposed method improves the reliability of identification of labeled oil. It increases because the presence and quantity of the marker in the oil product is judged by the presence of the optical spectrum characteristic of the marker in the region λ = 350 ... 600 nm and by the intensity of many optical lines of the spectrum, and not just by one absorption line at λ = 535 nm, as in prototype.

The use for identification of hydrocarbons, for example, oil refining products, of multiple spectral lines that coincide with the parameters of the reference sample can significantly increase the reliability of the analysis result compared to using information about one spectral line. When using the fact of coincidence of many spectral lines, the probability of random coincidence is significantly reduced, for example, due to the error of the measuring equipment. The elimination of random coincidence significantly increases the reliability of identification. Moreover, the identification process is significantly simplified in comparison with the prototype - due to the lack of need for acidification of the selected sample of labeled oil product with hydrochloric acid.

In addition, the proposed identification method makes it possible to identify a labeled oil without sampling, directly in the flow of a substance (oil).

The present invention satisfies the criteria of novelty, since when determining the level of technology, no means have been found that have characteristics that are identical (that is, they coincide in the functions performed by them and the form in which these signs are performed) to all the signs listed in the claims, including the purpose of the application.

The proposed method has an inventive step, since no technical solutions have been identified that have features that match the distinguishing features of this invention, and the popularity of the influence of distinctive features on the achievement of these technical results is not established.

The claimed technical solution can be implemented in industry, in trade, in law enforcement through the use of well-known standard devices, for example spectrophotometers of various companies. As a result, the claimed technical solution meets the criterion of "industrial applicability" to the invention.

Information sources

1. Gareishina A.Z. A composition comprising a petroleum product and a marker, a method and a solution for marking a petroleum product, a method for identifying a petroleum product and a method for producing a marker / A.Z. Gareishina, E. V. Petukhova, D. V. Yusupova, N. A. Lebedev, T .N. Chertilina, A.Z. Ponomareva // Patent for invention RU 2218381, C10L 1/00, С10М 159/02, C10N 30:20, Priority from 07.22.02.-2003. Bull. Number 34.

2. Hubbard R. The biosynthesis of Prodigiosin, the tripyrrylmethene pigment from Bacillus prodigiosus (Serratia marcescens) / R. Hubbard, C. Rimington // Biochem. - 1950. - V.46, No. 2. - P.220-225.

Claims (1)

A method for identifying petroleum products labeled using a biological marker-pigment prodigiosin, which involves sampling an oil product containing a detectable amount of a marker, characterized in that the presence and quantitative content of the marker in the oil product is determined by the presence of an optical spectrum in the wavelength region of 350-600 nm without prior acidification samples and with the possibility of analysis in the stream.

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