RU2506571C1 - Method for measuring quality of oil products - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: use: for measuring of product quality. Substance: consists in the fact that in the process of measuring of remote NMR spectra of several reference oil products with known values of quality indicators covering the full range of possible changes, the fixed principal chemical shift determines the position of the absolute maximum of the NMR spectrum of each oil product, characterised by the fact that on the basis of shot spectra they determine analytical dependence linking the normalised values of each of the quality with the main chemical shift of the reference oil product, which is stored in a processor, the measured NMR of the controlled product that captures the main chemical shift q_X. After that, each specific indicator of fuel quality is determined by the dependence connecting with the main indicator of quality with the chemical shift. The dependence is determined during calibration according to reference oil.

EFFECT: providing opportunities to facilitate measurements of quality of oil products without compromising accuracy.

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Description

The method relates to measuring and control equipment and can be used to quickly measure the quality of petroleum products without burning and analysis of the composition, for example, the octane number of gasolines, cetane number of diesel fuels, sulfur content, density, viscosity and others.

Known analogues of the invention are optical, spectrometric and dielectric methods for measuring fuel quality indicators based on measuring the absorption coefficient of optical radiation and permittivity at different frequencies indirectly associated with a determined quality indicator (RF patent No. 2112956 MKI: G01N 21/35, publ. 06/10/1998; RF patent No. 2091758 IPC: G01N 21/35, publ. 09/27/1997; RF patent No. 2334971 C2, publ. 09/27/2008 IPC: G01N 21/35, ac SU No. 1689817 IPC: G01N 23/00, publ. 07.11.1991; utility model RU No. 10463 G01N 25/20, publ. 16.07.1999). Methods of indirect and cumulative measurements are also known, consisting in the fact that a set of parameters is measured that are indirectly related to the measured parameter, which is then determined as a result of calculation using a known functional dependence, or as a result of solving a system of algebraic equations. A known measurement method based on the use of exemplary measures, when exemplary values of the measured parameter are supplied to the input of the measuring device, and as a result of solving the system of equations, the additive and multiplicative error components are excluded [Kulikovsky K.L., Cooper A.O. Methods and means of measurement. M .: Higher school, 1987].

Also known are methods and devices based on the removal and analysis of NMR spectra of the studied products: patent RU No. 2333476 C1, publ. 09/10/2008; RU No. 2256931 C1, publ. 07/20/2005; RU No. 2323222 C1, publ. 05/05/2008; RU No. 2359257 C1, publ. 06/20/2009, in which the chemical shift and intensity of the NMR signal is used to judge the chemical composition and quality indicators of petroleum products.

The disadvantages of analogues are the complexity of their implementation, since it is not always possible to accurately determine the conversion functions that connect the measured parameters with the initial quality indicators of oil products, due to the diversity of the component composition of hydrocarbon fuels.

The prototype of the invention is a calibration-based method, which consists in measuring the electrophysical parameters of the controlled oil product, indirectly related to the determined value, where during the calibration process, a set of parameters corresponding to the known (reference) values of the determined value, which are stored in the processing device, is measured, and in the measurement process, the desired value is determined by special formulas that relate the results of measurements and calibrations (RF patent No. 2227320, publ. 20.0 4.04).

The disadvantage of the prototype is the complexity of the technical implementation associated with the need to use a variety of sensors that measure different quality indicators, which ultimately complicates the design, reduces reliability, complicates the setup, commissioning and operation of the device in extreme climatic conditions.

The task is: to reduce the measurement accuracy to simplify the technical implementation of the method, by using an NMR sensor, in cases where the conversion function or the equations relating the measured parameters to the desired indicator are unknown.

The solution to this problem is achieved by the fact that in the known method, which is based on the method of nuclear magnetic resonance spectrometry using calibration, which consists in taking the NMR spectra of several reference petroleum products with known values of quality indicators covering the full range of possible changes, the main chemical the shift determined by the position of the absolute maximum of the NMR spectrum of each oil product, characterized in that on the basis of the recorded spectra are determined analyte cal depending linking normalized values for each quality metric to the main chemical shift reference oil

,

,

,

,

where k = 1, 2 ... n - corresponds to the number of the quality indicator,

- нормированное значение показателя качества,

- the normalized value of the quality indicator,

Q _k and Q _{k, max} - the current and maximum values of the k-th quality indicator, which is stored in the processing device, measure the NMR spectrum of the controlled product, for which the main chemical shift q _X is recorded, after which each quality indicator is determined by the formula

.

.

where Q _{k, X} is the k-th quality indicator of the controlled oil product.

A positive effect is achieved due to the fact that during the calibration process, values are laid down that allow you to create a device conversion function for each quality indicator, while only one sensor is used.

Let there be a petroleum product for which it is necessary to determine the above set {Q _k }, (k = 1 ... n) of quality indicators by NMR methods, that is, based on determining the chemical shift relative to the standard (s) with known values of the studied parameters, n is the number of indicators quality. A chemical shift determines the relative (with respect to the standard) frequency of the nuclear magnetic resonance of a substance. Moreover, each quality indicator varies in the range [Q _{k, min} ÷ Q _{k, max} ]. The chemical shift is determined by the NMR sensor by spectrometric characteristics, the form of which depends on the chemical composition and structure of the substance. In particular, for petroleum products from the presence of hydrogen and oxygen atoms and their compounds. A typical NMR spectrum of gasoline is shown in figure 1.

In the NMR spectrum, as a rule, there are several extrema; in this invention we will use the main chemical shift (q) corresponding to the absolute maximum.

In the general case, the main chemical shift caused by a change in the quality indicators of the oil product from the reference value can be described by the function:

Function (1) is unknown. Considering that any measurement process implies, in addition to collecting and processing information, also the operation of calibrating the device according to known reference parameters, a measurement algorithm is proposed to solve the problem, the essence of which is that with an unknown function F, a calibration model of the measurement process is compiled. For this, several fuel samples are taken with known values of quality indicators determined by laboratory methods and they are assigned the same number of chemical shift counts. At the same time, it is necessary that the reference fuels completely cover the expected range of changes in the determined quality indicators. The number of model fuels N must be not less than the number of determined quality indicators n (N≥n). Suppose there are N calibration fuel samples. Each of these samples has its own set of quality indicators. For example, the first sample (N = 1) has a set of quality indicators Q _1,1 , Q _1,2 , ... Q _{1, k} ... Q _{1, n} . Sample N = i has a set of quality indicators Q _{i, 1} , Q _{i, 2} , ... Q _{i, k} ... Q _{i, n} . The sample (N = N) has a set of quality indicators Q _N.1 , Q _N.2 , ... Q _{N, n} . Here, the first index corresponds to the number of the calibration sample, the second index to the number of the quality indicator.

Quality indicators Q _k have different dimensions, therefore, their image on the same graph is impossible. However, if quality indicators are taken as normalized, defined as the current value divided by the maximum value, then illustration becomes possible in relative (dimensionless) units. For example, if the quality indicator Q _k has a range of variation [Q _kmin ÷ Q _{k, max} ], then the normalized quality indicator is determined by the formula

Then, for normalized quality indicators, any oil product can be characterized by a set of functions (graphs), shown in figure 2, linking quality indicators with a chemical shift.

Thus, according to a set of experimental data for each quality indicator, an analytical dependence is compiled connecting the quality indicator with a chemical shift

,

,

The set of dependencies obtained is stored in the processing device. To assess the quality indicators of the test fuel, its NMR spectrum is taken, its basic chemical shift is determined. The range of normalized quality indicators for an arbitrary value of the chemical shift q _{x is} determined by the formula

The absolute value of the quality indicator is determined by the formula

The approximation of the experimental points can be carried out by the least squares method with various functions of a given form, in the simplest case a power polynomial. You can use third-party software systems: Mathcad, Maple, Matlab.

The proposed measurement method does not require accurate knowledge of the function linking the desired quality indicator with readings of the NMR characteristics of the studied sample parameters. It involves the creation of a mathematical model based on reference samples of fuels with known values of quality indicators. At the same time, quality indicators are determined without analysis of the chemical composition and with measurements by a single sensor.

Claims (1)

A method of measuring the quality of petroleum products by nuclear magnetic resonance spectrometry (NMR spectrometry), based on calibration, which consists in taking the NMR spectra of several reference petroleum products with known values of quality indicators covering the full range of possible changes, the main chemical shift is determined, determined the position of the absolute maximum of the NMR spectrum of each oil product, characterized in that, based on the recorded spectra, analytic skie depending linking normalized values for each quality metric to the main chemical shift reference oil

,

where k = 1,2, ... n - corresponds to the number of the quality indicator,

- the normalized value of the quality indicator,
Q _k and Q _{k, max} - the current and maximum values of the k-th quality indicator,
when measuring the NMR spectrum of the controlled product, the main chemical shift q _X is determined, the necessary previously determined analytical dependence is sampled, after which each quality indicator is determined by the formula

where Q _{k, X} is the k-th quality indicator of the controlled oil product.