RU2646526C1 - Method of measuring composition and concentration of impurities in low-polarity liquids - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: method of measuring composition and concentration of impurities in low-polarity liquids comprises stages at which alternating voltage of alternating frequency in the range from 10 Hz to 1 mhz is supplied to its electrodes after filling of the inter-electrode space of the measuring sensor with investigated liquid, and its spectral characteristic is measured. For this purpose, electric capacitance of the measuring sensor is determined in the investigated liquid in case of step change of the frequency. The pitch of the frequency variation is determined depending on frequency range. The working frequency is determined for which purpose a base frequency of transducer signal is measured without its connection to the measuring sensor and the reference capacitor, the reference frequency of converter signal with reference capacitor connected thereto and frequency of the converter signal with the measuring sensor connected thereto. The capacitance of the sensor in liquid under test is determined on the basis of the measured frequencies.

EFFECT: reduced time and increased accuracy for determination of dielectric parameters in measured medium, simplified hardware component.

2 cl

Description

The invention relates to measuring technique and can be used to reliably determine the component composition and impurities in liquid dielectrics used in the petroleum product supply system, medicine and scientific research.

Various methods for determining dielectric parameters in liquid dielectrics are known in the art. For example, a method is known in which a signal modulated in frequency by a sawtooth low-frequency signal and a low-frequency harmonic signal with a modulation index corresponding to a 2-fold decrease in the power of the resonance curve is applied to the resonator input, and the half power level is determined from the position of the peak of the resonance curve. The quality factor is then calculated from certain frequency values corresponding to the peak of the resonance curve and half power levels (see, for example, RU 1493958, publ. 15.07.1989).

A method of measuring the complex dielectric constant of liquids in a wide frequency range in one cell is also known as the closest analogue, while in the frequency range above 100 MHz, the dielectric constant is calculated through the measured values of the complex transmission coefficient of the electromagnetic wave (scattering matrix parameter S ₁₂ ), and the frequency range below 1 MHz - through the measurement of the total conductivity (see, for example, RU 2509315, publ. 20.11.2013).

The disadvantage of these methods is that they can only be used to measure high values of dielectric parameters (for example, Q factors - 10 ⁶ and higher), while the measurement error is significantly affected by the instability of the frequency of the excitation signal and the temperature regime. Also the disadvantages of these technical solutions are the complexity of their implementation and low accuracy due to measurement error.

The task to which the claimed technical solution is directed is to develop a method for measuring the composition and concentration of impurities in low-polar liquids, including trace metals and sulfur, by the peak characteristics of the impedance spectra obtained by analyzing liquid dielectrics in the low frequency range.

The problem is solved due to the fact that in the method for measuring the composition and concentration of impurities in low-polar liquids, which includes introducing the test liquid into a measuring sensor equipped with a reference capacitor and made in the form of a filled capacitor, applying an alternating voltage alternating voltage to the electrodes of the measuring sensor, according to of the invention, an alternating voltage of a variable frequency is applied to the electrodes of the measuring sensor in the range from 10 Hz to 1 MHz and the spectral characteristic is measured measuring sensor by determining the electric capacitance of the measuring sensor in the test fluid with a step change in frequency, while for each frequency point the working frequency and resistance of the reference resistors are set taking into account the complex value of the resistance of the measuring sensor, each measurement step is synchronously digitized through three channels - the reference channel signal, the channel of the reference signal and the channel of the measured signal for each frequency point; for each channel, average e values of the obtained values, the obtained values lead to a bipolar signal, calculate the rms values and based on the obtained data calculate the cosines of the phase angle and the cosines of the dielectric loss angles for the reference capacitor and for the measuring sensor, determine the dielectric loss angles and the phase error corresponding to the values of the angle difference of the phase shift between the reference capacitor and the measuring sensor, spectrogram plots are constructed from the obtained values, The component composition of the product.

To determine the electric capacitance of the measuring sensor, the base frequency of the transmitter signal is measured without connecting it to the measuring sensor and the reference capacitor, the reference frequency of the converter signal with the connected capacitor connected to it and the frequency of the converter signal with the measuring sensor connected to it, the capacitance of the measuring sensor is determined based on the measured frequencies in the test fluid according to the formula:

Where

C _x - the capacity of the measuring sensor in the test fluid, f;

F _bas - signal frequency of a capacitive transducer without connecting it to a measuring sensor and a reference capacitor, Hz;

F _etal - frequency signal of a capacitive converter with a reference capacitor connected to it, Hz;

F _sens is the signal frequency of the capacitive transducer with a measuring sensor connected to it, located in the test fluid, Hz;

C _etal is the capacitance of the reference capacitor, F.

The technical result provided by the given set of features is to reduce the dimensions of the measuring sensor and simplify the hardware component through the use of impedance spectroscopy in a wide range of low frequencies from 10 Hz to 1 MHz at low electric field strength, reduce time and increase the accuracy of determination of dielectric parameters of liquid dielectrics by peak characteristics of the obtained spectrograms expressing the maximum information about molecular interactions in the dielectric ke and, as a consequence, the composition of the medium.

The proposed method for measuring the component composition and impurities in a low-polar liquid dielectric is based on the dependence of dielectric loss on frequency under the influence of electric field strength to polarize the dielectric in the frequency range with a linearly varying frequency and then determine the phase shift angles of the measuring sensor relative to the reference capacitor. The method is applicable at frequencies from 10 Hz to 1 MHz and consists in the following.

The measuring sensor is made in the form of a capacitor filled with the test liquid, namely a dielectric, and is also equipped with a reference capacitor. After filling the interelectrode space of the measuring sensor with the studied liquid, alternating voltage of variable frequency in the range from 10 Hz to 1 MHz is applied to its electrodes and its spectral characteristic is measured. To do this, determine the electrical capacitance of the measuring sensor in the test fluid with a step change in frequency. The frequency step is determined depending on the frequency range. The frequency at each measured point is hereinafter called the operating frequency. To do this, measure the base frequency of the transmitter signal without connecting it to a measuring sensor and a reference capacitor, the reference frequency of the converter signal with a reference capacitor connected to it, and the frequency of the converter signal with a measuring sensor connected to it. Based on the measured frequencies, the sensor capacitance in the test fluid is determined by the formula:

Where

With _x - the capacity of the measuring sensor in the test fluid, f;

F _bas - signal frequency of a capacitive transducer without connecting it to a measuring sensor and a reference capacitor, Hz;

F _etal - frequency signal of a capacitive converter with a reference capacitor connected to it, Hz;

F _sens is the signal frequency of the capacitive transducer with a measuring sensor connected to it, located in the test fluid, Hz;

C _etal is the capacitance of the reference capacitor, F.

Next, for each frequency point, the working frequency and resistance of the reference resistors are set. For this, the complex value of the resistance of the measuring sensor (impedance) is calculated by the formula:

;

;

Where

X _{with the} complex value of the resistance, Ohm;

F is the operating frequency at the measured point, Hz;

C _x - the capacity of the measuring sensor in the test fluid, F.

Each measurement step is synchronously digitized in three channels - the channel of the reference signal, the channel of the reference signal and the channel of the measured signal for each frequency point. For each channel, the average values of the obtained values are calculated:

;

;

Where

SR _canal1 - average value of the channel of the reference signal, units;

N is the number of digitization points, units

Data1 [i] - each of the N digitized values of the channel of the reference signal, units

;

;

Where

SR _canal2 - the average value of the channel of the reference signal, units

N is the number of digitization points, units

Data2 [i] - each of N digitized values of the channel of the reference signal, units

;

;

Where

SR _canal3 - the average value of the channel of the measured signal, units

N is the number of digitization points, units

Data3 [i] - each of N digitized values of the measuring channel of the measured signal, units

The obtained values are reduced to a bipolar signal using the formulas:

Data1dp [i] = Data1 [i] -SR _canal1

Where

Data1dp [i] is the result of converting the measured signal along the channel of the reference signal into a bipolar signal, units

Data1 [i] - each of the N digitized values of the channel of the reference signal, units

SR _canal1 - the average value of the channel of the reference signal, units

Data2dp [i] = Data2 [i] -SR _canal2,

Where

Data2dp [i] - the result of the conversion of the measured signal through the channel of the reference signal into a bipolar signal, units

Data2 [i] - each of N digitized values of the channel of the reference signal, units

SR _canal2 - the average value of the channel of the reference signal, units

Data3dp [i] = Data3 [i] -SR _canal3,

Where

Data3dp [i] is the result of converting the measured signal along the channel of the measured signal into a bipolar signal, units

Data3 [i] - each of N digitized values of the channel of the measured signal, units

SR _canal3 - the average value of the channel of the measured signal, units

Based on the obtained calculations, the rms values are calculated:

;

;

Where

Val1 - the rms value of the bipolar signals of the channel of the reference signal, units

Data1dp [i] is the result of converting the measured signal along the channel of the reference signal into a bipolar signal, units

N is the number of digitization points on, units

;

;

Where

Val2 - the rms value of the bipolar channel signals of the reference signal, units

Data2dp [i] - the result of the conversion of the measured signal through the channel of the reference signal into a bipolar signal, units

N is the number of digitization points, units

;

;

Where

Val3 - the rms value of the bipolar channel signals of the measured signal, units

Data3dp [i] is the result of converting the measured signal along the channel of the measured signal into a bipolar signal, units

N is the number of digitization points, units

Received bipolar signals are converted to a scale from 0 to 1:

;

;

Where

DataG [i] - values on the channel of the reference signal, recounted in the range 0 ... 1, units

Data1dp [i] is the result of converting the measured signal along the channel of the reference signal into a bipolar signal, units

Val1 - the rms value of the bipolar signals of the channel of the reference signal, units

;

;

Where

DataE [i] - values on the channel of the reference signal, recounted in the range 0 ... 1, units

Data2dp [i] - the result of the conversion of the measured signal through the channel of the reference signal into a bipolar signal, units

Val2 - the rms value of the bipolar signals of the measured channel of the reference signal, units

;

;

Where

DataX [i] - values on the channel of the measured signal, recounted in the range 0 ... 1, units

Data3dp [i] is the result of converting the measured signal along the channel of the measured signal into a bipolar signal, units

Val3 - the rms value of the bipolar channel signals of the measured signal, units

The cosine of the phase angle of the reference capacitor is calculated

;

;

Where

cosFil - cosine of the phase angle of the reference capacitor, units

DataG [i] - values on the channel of the reference signal, recounted in the range 0 ... 1, units

DataE [i] - values on the channel of the reference signal, recounted in the range 0 ... 1, units

N is the number of measurement control points on a linear scale, units

The cosine of the phase angle of the measuring sensor is calculated

;

;

Where

cosFi2 - cosine of the phase angle of the measuring sensor, units

DataG [i] - values on the channel of the reference signal, recounted in the range 0 ... 1, units

DataX [i] - values on the channel of the measured signal, recounted in the range 0 ... 1, units

N is the number of measurement control points on a linear scale, units

The cosine of the dielectric loss angle is calculated for the reference capacitor

;

;

Where

FIEcos - cosine of the dielectric loss angle for the reference capacitor, units

Val1 - the rms value of the bipolar signals of the channel of the reference signal, units

Val2 - the rms value of the bipolar signals of the measured channel of the reference signal, units

cosFi1 - cosine of the phase angle of the reference capacitor, units

The cosine of the dielectric loss angle is calculated for the measuring sensor:

;

;

Where:

FIScos - cosine of dielectric loss angle for a measuring sensor, units

Val1 - the rms value of the bipolar signals of the channel of the reference signal, units

Val3 - the rms value of the bipolar channel signals of the measured signal, units

cosFi2 - cosine of the phase angle of the measuring sensor, units

Dielectric loss angles for a reference capacitor are determined

;

;

Where

FIE - dielectric loss angle of the reference capacitor, deg.

FIEcos - cosine of the dielectric loss angle for the reference capacitor, units

The dielectric loss angles for the measuring sensor are determined

;

;

Where

FIS - dielectric loss angle of the measuring sensor, deg.

FIScos - cosine of dielectric loss angle for a measuring sensor, units

Determine the phase error

DFI = FIE-FIS

Where

DFI - phase error, deg.

FIE - dielectric loss angle of the reference capacitor, deg.

FIS - dielectric loss angle of the measuring sensor, deg.

Based on the calculated DFI / operating frequency values, spectrogram plots are constructed, the values of which characterize the studied liquid by impurities, and by comparing the areas obtained by the spectrum of the studied liquid with the sample spectrum, a conclusion is drawn on the actual parameters of the component composition of the studied liquid.

A comparative analysis of the possible application of the proposed method with existing methods especially emphasizes its versatility in the process of conducting studies of molecular interactions in liquid dielectrics.

Claims (9)

1. A method for measuring the composition and concentration of impurities in low-polar liquids, which includes introducing the test liquid into a measuring sensor equipped with a reference capacitor and made in the form of a capacitor to be filled, applying an alternating frequency AC voltage to the electrodes of the measuring sensor, characterized in that it is supplied to the measuring electrodes the sensor AC voltage of a variable frequency in the range from 10 Hz to 1 MHz and measure the spectral characteristic of the measuring sensor by determining the electric capacitance of the measuring sensor in the liquid under investigation with a step change in frequency, while for each frequency point the working frequency and resistance of the reference resistors are set taking into account the complex value of the resistance of the measuring sensor, each measurement step is synchronously digitized in three channels - the channel of the reference signal, the channel of the reference of the signal and the channel of the measured signal for each frequency point; for each channel, average values of the obtained values calculated This leads to a bipolar signal, the rms values are calculated, and based on the obtained data, the cosines of the phase shift angles and the cosines of the dielectric loss angles for the reference capacitor and for the measuring sensor are determined, the dielectric loss angles and the phase error corresponding to the values of the difference in the phase shift angles between the reference capacitor and using a measuring sensor, spectrogram plots characterizing the component composition of the product are constructed from the obtained values. 2. The method according to p. 1, characterized in that to determine the electrical capacitance of the measuring sensor measure the base frequency of the transmitter signal without connecting it to the measuring sensor and the reference capacitor, the reference frequency of the transmitter signal with a connected reference capacitor and the frequency of the transmitter signal connected to him measuring sensor, based on the measured frequencies determine the capacity of the measuring sensor in the test fluid according to the formula:

Where C _x - the capacity of the measuring sensor in the test fluid, f; F _bas - signal frequency of a capacitive transducer without connecting it to a measuring sensor and a reference capacitor, Hz; F _etal - frequency signal of a capacitive converter with a reference capacitor connected to it, Hz; F _sens is the signal frequency of the capacitive transducer with a measuring sensor connected to it, located in the test fluid, Hz; C _etal is the capacitance of the reference capacitor, F.