RU2715934C1 - Analyzer for selective determination of volatile aromatic hydrocarbons - Google Patents

Abstract

FIELD: instrument engineering.

SUBSTANCE: invention relates to instrument-making and concerns an analyzer for selective determination of volatile aromatic hydrocarbons in a gaseous medium. Analyzer comprises a chemosensor element, a radiator and a system for controlling and recording the analysis results. Chemosensory element has a sensor layer containing a fluorophore which is sensitive to each determined component. Irradiator has a UV light source for exciting a sensory layer fluorescence, and a blue light source optically connected to the chemosensor element and intended for illumination thereof. System for controlling and recording the analysis results is configured to alternately switch on the UV light source and the blue light source, as well as to measure the fluorescence intensity of the sensor layer and intensity of the blue light transmitted through the sensor layer.

EFFECT: technical result is increase in the measurements accuracy.

1 cl, 1 dwg

Description

The invention relates to instrumentation and can be used as a portable analyzer to determine the ambient air content of volatile aromatic hydrocarbons, such as benzene, toluene, xylenes.

Analyzers are known that make it possible to selectively determine the content of volatile aromatic hydrocarbons in a gaseous medium, the operation of which is based on the excitation of fluorescence of chemosensory elements sensitive to detected hydrocarbons.

Thus, a known analyzer of the content of volatile organic compounds in a gas environment [RU 2427822]. This device contains a matrix of fluorescent chemosensory elements, the material of each of which is sensitive to one of the determined components. The device also contains an emitter, including a set of LED light sources, each of which is optically coupled to one of the chemosensory elements and is designed to excite its fluorescence. The device includes a control and recording system for the analysis results, which provides alternating periodic switching of each light source and measuring the fluorescence intensity of each chemosensor element in the corresponding spectral channel, as well as determining component concentrations based on these measurements.

This device provides the ability to selectively determine the concentration of a number of components of a mixture of volatile organic compounds.

However, the device in question is complex in design and consumes a significant amount of energy, which is associated with the presence of a matrix of chemosensory elements and the presence of its own light source in each spectral measuring channel. In addition, this device does not take into account the effect of changes in humidity and temperature of the gaseous medium on the results of determination of concentrations.

Closest to the claimed analyzer is a device with which a method for selectively determining the concentration of volatile aromatic hydrocarbons, such as benzene, toluene and xylenes in a gas mixture, is described in [RU 2534729]. The specified device is selected by the authors as the closest analogue.

This analyzer uses a single fluorescent chemosensory element having a sensor layer containing a fluorophore selected from the group of boron β-diketonates, sensitive to each of the determined components. In particular, boron difluoride dibenzoylmethonate (DBMBP ₂ ) or its methyl or methoxy derivative was used as a fluorophore.

The analyzer contains an irradiator, including an LED UV light source, the radiation of which lies in the wavelength range of 355-400 nm. The specified light source is designed to excite fluorescence of the sensor layer of the chemosensor element, the fluorescence spectrum of which lies in the wavelength range of 400-550 nm.

The analyzer also contains a control system and recording the results of the analysis, made with the possibility of periodic pulsed switching on of the LED UV light source and measuring the fluorescence intensity of the sensor layer.

As a fluorescence intensity sensor, the control and recording system for the analysis results includes, in particular, a fiber optic spectrometer.

The fluorescence intensity is measured in the control and recording system of the analysis results in four spectral channels corresponding to the spectral regions in which the maximum fluorescence intensity of the fluorophore and its exciplexes with benzene, toluene, and xylenes is observed.

The control system for recording and recording the results of the analysis contains a calculator capable of calculating, based on the above measured values, the relative fluorescence intensities of the spectra of the fluorophore and its exciplexes with benzene, toluene and xylenes, and determining the concentration of each hydrocarbon component from the indicated relative intensities (using previously obtained calibration curves) .

This device allows you to selectively determine the concentration of volatile aromatic hydrocarbons, while, thanks to the use of a single chemosensor element, the design of the device is simplified and its energy consumption is reduced.

However, this device does not take into account the effect of changes in humidity and temperature of the gaseous medium on the results of determining the concentrations of volatile aromatic hydrocarbons.

The problem, the solution of which is provided by the implementation of the invention, is to increase the accuracy of the device.

The essence of the invention lies in the fact that in the analyzer for the selective determination of volatile aromatic hydrocarbons in a gaseous medium, including a fluorescent chemosensor element having a sensor layer containing a fluorophore sensitive to each detected component, an irradiator including a UV light source, optically coupled to the chemosensor element and designed to excite fluorescence of the sensor layer, a control system and recording the results of the analysis, made with the ability to control VK by irradiating a UV light source and measuring the fluorescence intensity of the sensor layer, according to the invention, the irradiator further comprises a blue light source optically coupled to the chemosensor element and intended for its illumination, while the control and recording of the analysis results is performed by alternately turning on the UV light source and the blue light source , as well as with the ability to measure the intensity of blue light transmitted through the sensor layer.

Essentially important in the inventive device is the presence in the irradiator of two alternately switched on UV and blue light sources, as well as the implementation of a control system and registration of the analysis results (hereinafter the control and registration system) with the ability to measure two types of light signals and process them.

Irradiation with UV light in the wavelength range of 355-400 nm excites fluorescence of the sensor layer in the wavelength range of 400-550 nm.

The first type of measured signals characterizes the fluorescent response of the sensor layer to irradiation with UV light. In this case, the magnitude and nature of the change in the indicated signal largely depends on the presence in the gas mixture (in ambient air) of the determined volatile components (analytes) to which the selected fluorophore is sensitive, and on their quantitative content.

The values of the signals of the first type in the absence of analyte correspond to the intensity of the fluorescence spectrum of the sensor layer in the measured spectral regions. A fluorophore in an excited state in the presence of analytes forms exciplexes (complexes) with them, the fluorescence spectra of which differ significantly. Moreover, the values of the signals of the first type noticeably change in the spectral regions corresponding to the fluorescence bands of these exciplexes, with respect to the values of the fluorescence spectrum of the sensor layer in these regions in the absence of analytes.

The calculator is capable of calculating from the measured values of the first type of signals the relative intensities of the spectra of the fluorophore and its exciplexes with analytes at the maximum of their fluorescence band and determining the concentration of each analyte present in the gas mixture from the intensities of the corresponding exciplex to the fluorophore intensity (taking into account the previously obtained calibration curves).

Irradiation with blue light does not lead to excitation of fluorescence of the sensory layer and to the formation of fluorophore exciplexes with analytes.

The signals of the second type characterize the dependence on the wavelength of the intensity of blue light transmitted through the sensor layer, part of which is lost due to absorption and scattering by the sensor layer material (hereinafter transmitted blue light).

The signals of the first and second types lie in the same spectral region corresponding to the wavelength range of blue light. It is important that the functional dependences characterizing them, although they differ, however, in the absence of analytes in the gaseous medium, they change in a correlated manner with changes in the humidity and temperature of the gaseous medium.

This allows, based on changes in the spectrum of transmitted blue light due to changes in humidity and temperature of the gas medium, to make appropriate adjustments to the calculated values used in the calculator to determine analyte concentrations, and thereby obtain more accurate analysis results taking into account real values of humidity and temperature .

So, the calculator is capable of calculating, based on the measured values of the signals of the second type, correction factors that take into account the change in these values with respect to the intensity of transmitted blue light obtained at normal values of humidity and temperature of the gas medium.

The calculator is also capable of correcting the calculated relative intensities of the spectra of the fluorophore and its exciplexes with analytes taking into account the indicated correction factors, as well as using the obtained adjusted values of the relative intensities to determine the concentration of each analyte.

Thus, the technical result achieved by the implementation of the invention is the ability to obtain analysis results taking into account changes in humidity and temperature of the gas environment, which leads to an increase in the accuracy of the device.

The figure shows a diagram of the inventive device.

The device comprises a fluorescent chemosensor element 1 and an irradiator including an LED source (2) of UV light with a wavelength range of 355-400 nm and an LED source (3) of blue light with a wavelength range of 440-520 nm.

Element 1 includes a sensor layer deposited on a solid support containing a fluorophore sensitive to each analyte. In particular, the device uses a fluorophore selected from the group of boron β-diketonates (for example, DBMBP ₂ or its methyl or methoxy derivative sensitive to benzene, toluene and xylenes).

Sources 2 and 3 are installed with the possibility of irradiating the sensor layer of the element 1, respectively, with UV light and blue light.

The device also includes a control and registration system 4, including means for measuring light signals of the first and second type from the element 1 in the wavelength range of 400-550 nm when the element 1 is irradiated with UV light and blue light, respectively.

The specified tool includes n measuring spectral channels corresponding to the maxima of the fluorescence band of the fluorophore and its exciplexes with analytes.

A spectral filter 5, a light signal intensity sensor 6, made in particular in the form of a photodiode, and an amplifier 7 are installed in each channel.

In particular, the device contains 4 spectral channels with a width of 50-55 nm with the centers of the bands of 410, 440, 480 and 520 nm, which corresponds to the spectral regions of the maximum fluorescence of the fluorophore and its exciplexes with benzene, toluene, xylenes.

The control and registration system 4 also contains a microcontroller 8 (hereinafter MC), which is connected to the outputs of the spectral measuring channels through the ADC 9.

The microcontroller 8 is configured to alternately periodically turn on sources 2 and 3 by generating clock pulses that control the inclusion of current generators 10 and 11, respectively associated with sources 2 and 3.

MK 8 contains a computer configured to process the signals emitted by the irradiator.

The device is mainly made in a portable design.

The device operates as follows.

When the device is turned on, the analyzed gas mixture located in it interacts with the sensor layer of element 1.

MK 8 generates clock pulses that control the alternate inclusion of sources 2 and 3.

When element 1 is irradiated with UV light from source 2, photodetectors 6 measure the light signal of the first type, which characterizes the fluorescence intensity of the fluorophore and its exciplexes with determined analytes.

Using a calculator in MK 8, the relative intensities of the spectra of the fluorophore and its exciplexes with analytes are calculated from the measured values of the first-type signal at the maximum of their fluorescence band.

When the element 1 is irradiated with blue light from the source 3, a second type of light signal is measured using photodetectors 6, which characterizes the intensity of transmitted blue light obtained at real values of humidity and temperature of the gas medium.

Using a calculator in MK 8, the measured values of the second type of signal are used to calculate correction factors that take into account the change in the specified signal with a change in humidity and temperature of the gas medium.

The obtained coefficients are used in the MK 8 computer to correct the relative intensities of the spectra of the fluorophore and its exciplexes with analytes.

Based on the obtained adjusted values of the above relative fluorescence intensities in the MK 8 calculator, analyte concentrations are calculated.

The results of determining the concentrations of analytes are displayed on the indicator (not shown in the drawing) through a digital output (not indicated by the position in the drawing) MK 8.

Claims (1)

An analyzer for the selective determination of volatile aromatic hydrocarbons in a gaseous medium, including a fluorescent chemosensor element having a sensor layer containing a fluorophore sensitive to each detectable component, an irradiator including a UV light source, optically coupled to a chemosensor element and designed to excite fluorescence of the sensor layer, a system control and recording the results of the analysis, made with the ability to control the inclusion of the UV light source and measure the intensity fluorescence of the sensor layer, characterized in that the irradiator additionally contains a blue light source that is optically coupled to the chemosensor element and is intended for its illumination, while the control and recording system for the analysis results is performed by alternately turning on the UV light source and the blue light source, as well as the ability to measure the intensity of blue light transmitted through the sensor layer.

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