RU2763682C1 - Optical system for determining aerosol compositions based on luminescent analysis of aerosol particles - Google Patents

Abstract

FIELD: measuring technology.

SUBSTANCE: invention relates to the field of measuring technology and relates to an optical system for determining the composition of aerosols based on the luminescence analysis of aerosol particles. The optical system contains at least one source of exciting radiation with a focusing means, a subsystem for transmitting optical signals from the flow of aerosol particles, a subsystem for spectral separation, and detectors of scattered and luminescent radiation. Light-emitting diodes are used as sources of exciting radiation. The focusing means consists of a converging lens, a guide mirror and an aspherical lens. The optical signal transmission subsystem contains elliptical and spherical mirrors, an optical return element, a diaphragm and a collimating lens. The spectral separation subsystem contains beam-splitting mirrors, a cut-off filter installed after the first beam-splitting mirror, and a neutral light filter installed in front of the scattered radiation receiver.

EFFECT: increasing the efficiency of collection of radiation and the information content of the optical signal, simplifying the design of the optical system and the requirements for its maintenance.

12 cl, 3 dwg

Description

The present invention relates to control and measurement technology, in particular to systems for optical control of the fractional-dispersed composition of aerosol particles, and can be used, for example, in monitoring the state of the environment.

This optical system is designed to determine the composition of aerosols based on the luminescent analysis of aerosol particles by the optical method of control in real time when monitoring the biological and environmental situation in crowded places, at transport facilities, at industrial enterprises and agricultural production, associated with the release of harmful, dangerous chemical and biological materials, in research programs to develop new methods and tools for the prevention and early diagnosis of diseases of various nature.

Currently known designs of several similar systems closest to the present invention.

So in the patent of the Russian Federation No. 2279663, IPC G01N 15/02, publ. November 20, 2005, describes a device for determining the composition of aerosols based on the analysis of the fluorescence of individual particles.

At the same time, in this patent, particles are excited by focused radiation from a lamp source, and luminescence radiation is collected using an optical system with a lens objective and directed through a diaphragm to photodetectors.

This device implements a spatial dilution of the areas of focusing the exciting and luminescent radiation. With the help of a processing system in the analysis of signals in three spectral ranges of luminescence and scattering, it is possible to determine the individual components of a multicomponent aerosol mixture.

However, the use of a lens objective for collecting luminescence radiation in the device leads to the presence of aberrations in the construction of the transverse size of the jet, and, as a result, to a decrease in the level of the recorded useful signal.

In addition, a lamp source with a large solid angle of the radiation generated by it in the analysis chamber gives elusive scattering, which leads to an increased optical background and also reduces the sensitivity of the device.

Also known optical system in the device registration of biological particles according to US patent for invention No. US 5895922, IPC C12M 1/34; G01N 15/14; G01N 21/64, publ. 04/20/1999

This optical system is based on lens optics used to collect luminescence, while the collection efficiency is low. The use of only one spectral range for collecting luminescence signals (400-540 nm) does not provide a satisfactory separation of particles according to the analyzed parameters. Additionally, the system is complicated by the presence of two continuous-wave lasers used for particle size analysis, which complicates the design of the device.

Known optical system and device for determining fluorescent components in aerosols (US patent for invention No. US 5999250, IPC G01N 15/14; G01N 15/00; G01N 21/64; G01N 15/02, publ. 07.12.1999).

This optical system uses several laser energy sources for sequential excitation of particles following a certain trajectory, and several receivers of optical radiation. To collect scattered and fluorescent radiation, elliptical mirrors are used, with the first focus of the mirrors coinciding with the particle excitation point, and the second with the location of the optical radiation receiver. The solid angle of radiation collection is estimated at 2 rad, which may limit the efficiency of detecting particles with a low fluorescence quantum yield.

Additionally, it should be noted that there is no possibility to register fluorescence in several optical ranges, and the presence of aberrations when fluorescent particles are displaced from the focus of the mirror. The decrease in sensitivity in the presence of aberrations can be compensated by an increase in the receiving aperture of optical radiation receivers, however, in this case, optical noise will inevitably increase, the methods of combating which are not considered in the proposed patent.

An optical recording system is also known in means for measuring the fluorescence spectra of individual aerosol particles taken from ambient air (US patent for invention No. US 2004125371, IPC G01N 21/64; G01J 3/30, publ. 01.07.2004).

This optical system consists of three lasers, a device for forming a stream of aerosol particles, a system of optical elements that transmit fluorescence and scattering radiation to the receiving areas of optical radiation receivers.

This optical system implements a method for measuring the fluorescence of aerosol particles in a flow, which includes the formation of a focused aerosol jet of a given diameter by a nozzle; determining the volume of the jet to be analyzed by crossing beams of two diode lasers orthogonal to the jet upstream of the particle flow; detection of light scattered from the vicinity of the analyzed volume by a set of detectors that record a certain wavelength of the diode laser beam; illumination of aerosol particles by a pulsed laser, the beam diameter of which corresponds to the size of the focused aerosol jet; collecting fluorescence emitted from particles in the analyzed volume and focusing it into the detection area. As an optical registration element for collecting and transmitting an optical signal to receivers, a Schwarzschild reflective lens is used, which has a numerical aperture of 0.5 with a luminescence collection efficiency of only 10-15%, which makes it necessary to use a laser as a radiation source. The object plane, aligned with the axis of the particle flow, is transmitted by the Schwarzschild lens to the receiving area of the optical radiation receiver.

This design of the optical system can lead to the dependence of the recorded signal on the position of the particle in the analysis area due to a number of factors, for example, due to the inhomogeneous sensitivity of the receiving area of the optical radiation detector. However, the correction of signals, excluding this effect in the optical system, is not provided in this patent. In addition, the mandatory presence of three lasers in the system, which is necessary for its correct operation, significantly complicates it.

This device provides for the possibility of increasing the efficiency of radiation collection through the use of an elliptical mirror. However, in this case, it is proposed to install the optical radiation receiver in the second focus, which also leads to the dependence of the particle radiation received by the receiver on the position in the analysis area.

In addition, in the case of using an elliptical mirror, the image of particles displaced from the first focus is aberrational. This can lead to an additional dependence of the signal strength on the position of the particle due to vignetting of the aberration image by the field stop of the spectrograph and to deterioration of the spectral separation of the aberration image. However, the issue of compensation for the effects of aberration of an elliptical mirror is also not considered in the patent.

In the patent RU 2448340, G01N 21/64 (2006.01) publ. On April 20, 2012, a method for recording scattering radiation and fluorescence of aerosol particles in a stream and a system for its implementation, chosen as a prototype, were described.

This optical system uses one or more laser (pulse) sources and sequential separation of signals over the spectral ranges of luminescence and scattering on the particles under study. To collect radiation, a deep elliptical mirror is used (70% radiation collection), focusing the air flow containing particles, excitation of this flow by a pulsed radiation source at the first focus of the elliptical mirror, image formation by the optical system, in which the cut (end) of the elliptical mirror is selected as the object plane. mirrors. In an optical registration system for image formation in two luminescence spectral channels and one scattering channel. In addition to an elliptical (or parabolic) mirror, the following are used: 1 condenser, 3 diaphragms, 4 lenses, 3 beam-splitting mirrors, 3 filters.

This optical system allows, due to a deep elliptical mirror, to increase the collected optical signal, to build images of various areas of the aerosol jet by diaphragming, thus increasing the signal-to-noise ratio by reducing light collection from the elements scattering the exciting radiation (nozzles and hoods), and to reduce the dependence on photosensitivity different areas of optical radiation receivers during the formation of a signal from a particle slightly displaced in an air jet from the first focus of an elliptical mirror.

However, this prototype is not without drawbacks.

Specified 70% light collection in the prototype is achieved by the formation of an aerosol jet and its excitation inside an elliptical mirror, for which 2 nozzles are introduced into the mirror to create a jet and 2 hoods for input and output of radiation. The presence of these elements in itself reduces the percentage of light collection, which in reality can be significantly lower than the indicated value.

In addition, hoods and nozzles are a source of optical noise due to the scattering of the exciting and luminescent radiation, to reduce which in the prototype and the aperture of the image area is used, resulting in a decrease in the optical signal.

Finally, the presence of an aerosol jet inside the main optical element - an elliptical mirror will inevitably lead to its contamination, which will further reduce the percentage of light collection, and, with a high probability, such an optical system may be inoperable in real operation, especially under conditions of high dust activity, since it will require frequent maintenance work to clean the elliptical mirror.

The use of pulsed radiation sources (including lasers) in the prototype is also not without drawbacks. The absence of the launch of a pulsed radiation source correlated with the arrival of a particular particle at a low concentration of particles in the jet will lead to a “missing” of registration of a particle whose time spent in the registration area does not coincide with the arrival time of the optical excitation pulse, which ultimately reduces the sensitivity of the prototype. If there is a preliminary trigger correlated with the arrival of a particle in the analysis area, then an increase in the number of particles to a value at which the trigger frequency exceeds the limiting frequency of the laser operation will lead to the exclusion of a certain fraction of particles from the analysis, which will reduce the information content of registration. And the decrease in the dependence on the photosensitivity of the receiving areas of the optical radiation receivers, for which the prototype uses diaphragming and the use of the end face of an elliptical mirror as an object plane during image formation, can be leveled by simply expanding the formed optical beam supplied to the entire aperture of the receiving area of the optical radiation receiver.

Finally, in general, the use of pulsed lasers is a relatively expensive and energy-consuming option, which is not always implemented taking into account the requirements for the purity of optical elements, especially those operating in pulsed modes with high radiation intensity.

The objective of the present invention is to increase the level and information content of the optical signal from the analyzed particles, which provides an increase in the efficiency of radiation collection, while simplifying and reducing the cost of the design and requirements for its maintenance.

The technical result of this invention is to increase the efficiency of radiation collection and the information content of the optical signal, while simplifying the design of the optical system and the requirements for its maintenance.

This technical result is achieved due to the fact that in the optical system for determining the composition of aerosols based on the luminescent analysis of aerosol particles, containing at least one source of excitation radiation, with a sequentially placed focusing means for focusing the excitation radiation on the flow of aerosol particles, with successively a placed optical subsystem for transmitting optical signals from a stream of aerosol particles, as well as a sequentially placed optical subsystem for spectral separation of optical signals from a stream of aerosol particles, containing beam-splitting mirrors, as well as receivers of scattered and luminescent radiation with receiving areas, LED sources are used as exciting radiation sources , the radiation of each of which is focused to one point of the aerosol jet using a focusing means consisting of a converging lens, a directing mirror and an aspherical lens, while ohm, the optical subsystem for transmitting optical signals from the flow of aerosol particles is made on the basis of an elliptical mirror and a spherical mirror, spatially separated from the area of the aerosol jet, and contains an optical return element configured to amplify the radiation intensity in the focus area of the LED sources, and at the output, the optical transmission subsystem optical signals from the flow of aerosol particles contains a diaphragm located in the second focus of the elliptical mirror, and a collimating lens, and the focus point of the LED radiation sources coincides with the focus of the spherical mirror and the first focus of the elliptical mirror, and the focus of the collimating lens is configured to form a parallel beam of scattered and luminescent optical signals from the flow of aerosol particles, coincides with the second focus of the elliptical mirror and the location of the diaphragm, while the optical subsystem of the spectral separation of optical signals from the flow of aerosol particles contains a cutting filter installed after the first beam-splitting mirror, and a neutral light filter installed in front of the scattered radiation receiver, while the light diameter of the optical and luminescent radiation beams coincides with the aperture of the receiving areas of the scattered and luminescent radiation receivers.

In one of the preferred embodiments, the optical system comprises two LED sources of excitation radiation, which are located opposite each other and have the same spectral range of radiation, while these LED sources of radiation are focused using two guiding mirrors located at an angle to each other, into one point of the aerosol jet.

In another of the preferred embodiments, the optical system contains two LED sources of excitation radiation of different spectral ranges, which are located at right angles to each other and are focused at one point of the aerosol jet using one directing mirror, while these LED sources of radiation of different spectral ranges are used alternately, at the choice of the operator, depending on the tasks of luminescence analysis.

It is advisable that in the optical system the optical subsystem for the spectral separation of optical signals from the flow of aerosol particles contains a rejector light filter, which is installed after the cutoff filter, and is configured to cut off exciting radiation from the luminescent radiation receivers from the second LED source of exciting radiation.

It is desirable that in the optical system the duration of switching on of each of the LED sources of excitation radiation of different spectral ranges correlates with the time spent by the aerosol particle in the jet in the region of analysis.

Preferably, in the optical system, the focusing means comprises a band pass filter placed between the converging lens and the guide mirror, wherein the band pass filter is configured to correct the spectral composition of the excitation radiation of the LED source.

It is advisable that an elliptical mirror be used as an optical return element in the optical system.

It is desirable that a parabolic mirror be used as the optical return element in the optical system.

Preferably, in the optical system, a photodetector is installed in the center of the optical return element, configured to control the power of the excitation radiation of each LED source of excitation radiation.

It is advisable that in the optical system, two spherical mirrors are used as two guiding mirrors, the focus of one of which coincides with the focus point of the LED sources of exciting radiation, and the focus of the second coincides with the location of the diaphragm.

It is desirable that in the optical system the converging lens has a spherical surface.

Preferably, in the optical system, the converging lens has an aspherical surface.

For a more complete disclosure of the invention, the following is a description of specific possible options for its execution, which are illustrated by the corresponding drawings.

Fig. 1 - the first version of the scheme of the optical system with two LED radiation sources located opposite each other.

Fig. 2 - the second version of the scheme of the optical system with two LED radiation sources located at right angles to each other, as well as with increased identification ability to separate aerosol particles in the flow.

Fig. 3 - graph of the spatial distribution of the intensity of the total radiation from aerosol particles in the second focus of the elliptical mirror in the absence and presence of an optical return element.

The first preferred embodiment of the optical system for determining the composition of aerosols based on the luminescent analysis of aerosol particles, contains two continuous LED sources 1 of excitation radiation, located opposite each other (Fig. 1), and in this case having the same spectral composition of the radiation.

The second preferred embodiment of the optical system contains LED sources 1 of exciting radiation, located at an angle of 90 ^{0 to} each other (Fig. 2). At the same time, the spectral composition of the radiation of the LED sources 1 is different, and the duration of the inclusion of each of the LED sources of exciting radiation of different spectral ranges correlates with the time spent by the aerosol particle in the jet in the analysis area.

Also, the optical system contains two focusing means for subsequent focusing of the exciting radiation of the LED sources 1 into one point of the aerosol jet.

In this case, each focusing means contains a converging lens 2 with a spherical or aspherical surface, a bandpass filter 3, a directing mirror 4 and an aspherical lens 5 (Fig. 2), and the bandpass filter 3 is configured to correct the spectral composition of the excitation radiation of the LED source 1.

With the help of converging lenses 2 (Fig. 1), installed in such a way that the focus of each converging lens 2 coincides with the emitting area of the LED source 1, a parallel radiation beam is formed to excite aerosol particles, which is directed into an optical subsystem for transmitting optical signals from the flow of aerosol particles, made on the basis of an elliptical mirror 7 and a spherical mirror 8, spatially separated from the area of the aerosol jet. Also, the optical subsystem for transmitting optical signals from the flow of aerosol particles contains an optical return element 6, configured to amplify the radiation intensity in the focus area of the LED sources, and at the output, the optical subsystem for transmitting optical signals from the flow of aerosol particles contains a diaphragm 9 located at the second focus of the elliptical mirror 7, and a collimating lens 10. Moreover, the focusing point of the LED radiation sources 1 coincides with the focus of the spherical mirror 8 and the first focus of the elliptical mirror 7, and the focus of the collimating lens 10, configured to form a parallel beam of scattered and luminescent optical signals from the flow of aerosol particles, coincides with the second focus of the elliptical mirror 7 and the location of the diaphragm 9. In this case, the collimating lens 10 forms a parallel beam of total radiation from aerosol particles, and the optical return element 6 can be made as in in the form of an elliptical mirror, and in the form of a parabolic mirror.

Also in the center of the optical return element 6 can be installed photodetector, configured to control the power of the exciting radiation of each LED source 1 of the exciting radiation.

In the first preferred embodiment of the optical system with LED sources 1 of exciting radiation located opposite each other (Fig. 1), the optical system has two guiding mirrors 4, which use two spherical mirrors, the focus of one of which coincides with the focus point of the LED sources 1 of the exciting radiation, and the focus of the second coincides with the location of the diaphragm 9.

The optical system also contains an optical subsystem for the spectral separation of optical signals from a stream of aerosol particles, containing the first beam-splitting mirror 11, as well as subsequent beam-splitting mirrors 12, as well as a scattered radiation receiver 13, luminescent radiation receivers 14, a cutoff filter 16 installed after the first beam-splitting mirror 11 , a neutral light filter 15 installed in front of the scattered radiation receiver 13, and a notch filter 17, which is installed after the cutoff filter 16, and is configured to cut off excitation radiation from the luminescent radiation receivers 14 from the second LED source 1. In this case, the light diameter of the optical and luminescent beams radiation coincides with the aperture of the receiving areas of the receivers scattered 13 and luminescent 14 radiation.

LED sources 1 of radiation of different spectral ranges are used alternately, at the choice of the operator, depending on the tasks of luminescence analysis, while the duration of the inclusion of each of the LED sources 1 of radiation of different spectral ranges correlates with the time spent by the aerosol particle in the jet in the analysis area.

Also, the optical system may contain light filters (not shown in the drawing) installed between the LED sources 1 and the analysis area, and made with the possibility of adjusting the spectral composition of the exciting radiation in the analysis area.

In the optical system, in the center of the optical return element 6, a photodetector (not shown in the drawing) can be installed, configured to control the power of the LED sources 1.

The presence of an optical return element 6 in the subsystem for generating luminescence and scattering signals from aerosol particles ensures an increase in the total signal of scattered and luminescent radiation from particles that have fallen into the analysis area at the output of the signal generation subsystem, which is shown in Fig. 3.

In the second preferred embodiment of the optical system (Fig. 2), LED sources 1 (A1 and A2) operate alternately, exciting aerosol particles with different wavelengths and forming different distributions of luminescence intensities over wavelengths, which increases the information content in the identification of aerosol particles.

For additional information, in this version of the optical system, one more receiver of optical radiation can be used, for which the spectral range of the received luminescent signal, as well as for receivers of scattered 13 and luminescent 14 radiation, is determined by the characteristics of the beam-splitting mirrors 11, 12. In this case, the number of information channels increases by a factor of two, which makes it possible to better separate different types of aerosol particles.

Optical system operates as follows.

Exciting radiation from LED sources 1 passes through bandpass filters 3 and converging lenses 2.

In this case, the converging lenses 2 are set in such a way that the focus of each converging lens 2 coincides with the emitting area of the LED source 1, forming a parallel beam of radiation for excitation of aerosol particles, which is directed by means of a directing mirror 4 to an aspherical lens 5, which focuses the radiation from the sources 1 in the center of the optical subsystem for transmitting optical signals from the flow of aerosol particles at the focus point of the LED excitation sources 1 (Fig. 1).

With the help of bandpass filters 3, a possible background illumination by the exciting radiation of the optical radiation receivers 13 and 14, which register luminescence signals, is cut off. In this case, the difference in optical densities in the transmission region, which coincides with the emission spectrum of the LED source 1, and the absorption (reflection) region should be at least 4, and the transmission of bandpass filters 3 in the transmission region should tend to 100%.

With the help of guiding mirrors 4, a parallel beam of radiation from LED sources 1 is directed to an aspherical lens 5. In this case, for the second variant of the optical system with increased separation identification ability (Fig. 2), a guiding mirror 4 is used, for which the radiation reflection coefficient for the LED source 1 ( A1) and the transmittance for LED source 1 (A2) should tend to 100%.

Using an aspherical lens 5, the radiation of LED sources 1 is directed to the analysis area, which is the point of intersection of the narrowest part of the aerosol jet (shown as a point, the direction of the jet is perpendicular to the plane of the figure) with the focus of the aspherical lens 5 and the focus of the optical return element 6 to amplify the intensity of the exciting radiation based on a spherical mirror 8. The presence of an optical return element 6 with a reflection coefficient, which should tend to 100%, allows you to increase the intensity of the exciting radiation in the analysis area up to 2 times (Fig. 3).

To collect and transmit luminescence radiation to optical radiation receivers 13 and 14, the invention uses an optical subsystem for generating luminescence and scattering signals from aerosol particles, made on the basis of an elliptical mirror 7 and a spherical mirror 8, spatially separated from the area of the aerosol jet, and the focus of the spherical mirror 8 and the first focus of the elliptical mirror 7 coincide with the focus of the aspherical mirror 5 and the optical return element 6. At the same time, the light collection efficiency, taking into account the presence of the optical return element 6, is at least 25%.

The second focus of the elliptical mirror 7 is chosen in the optical system as the plane optically conjugated with the receiving platforms of the optical radiation receivers 13 and 14, while aperture 9 is used to determine the dimensions of the jet area containing aerosol particles in the analysis area transmitted to the receiving platforms. , which is also located in the second focus of the elliptical mirror 7, and the focus of the converging lens 10, which forms a parallel beam for delivery to the receiving areas of the radiation detectors 13, 14, also coincides with the second focus of the elliptical mirror 7 and the location of the diaphragm 9.

A parallel beam, consisting of an image of a jet of aerosol particles formed in luminescent and scattered radiation, determined by the size of the diaphragm 9, is then fed into the optical subsystem for the spectral separation of optical signals from a stream of aerosol particles, based on beam-splitting mirrors 11, 12. First, the beam of aerosol particles is fed to the beam-splitting mirror 11, the reflection coefficient of which for the radiation of the LED source 1 (A1) is close to 100%. The radiation elastically scattered by aerosol particles enters the optical radiation receiver 13, while a neutral light filter 15 can be used to change the radiation intensity.

In the first version of the optical system (Fig. 1), at least two receivers of luminescent radiation 14 are further used, while the radiation of continuous LED sources 1 and radiation elastically scattered by aerosol particles is reduced by a cut-off filter 16 and a notch filter 17 with a difference in optical densities to prevent background illumination. within the limits of the transmission and cutoff range of at least 2.

In the second version of the optical scheme (Fig. 2), LED sources 1 (A1) and (A2) operate alternately, exciting aerosol particles with different wavelengths and forming different distributions of luminescence intensities over wavelengths, which increases the information content in the identification of aerosol particles. To obtain additional information in this version of the optical system, one more optical radiation receiver 14 can be used, for which the spectral range of the received luminescent signal, as for other receivers 14, is determined by the characteristics of the beam-splitting mirrors 12.

Since the LED sources 1 used in the invention are fundamentally continuous, the resulting optical signal does not suffer in terms of level and information content from missing registration of individual particles (as in the prototype) associated with the operation of the laser in a pulsed mode.

Thus, the claimed optical system allows the use of simple LED excitation sources 1, while combining them in a pair with the same spectral composition of radiation to increase the intensity in the analysis area or with a different spectral composition to increase the information content in the identification of aerosol particles, it also allows you to remove the aerosol jet from areas of contact with the optical elements of the image transmission system to the optical radiation receivers 13 and 14, spatially dividing them, while maintaining the light collection efficiency at a high level, thus minimizing the need for maintenance of the optical system when working in real conditions.

Also, the presented optical system allows you to get rid of skips in the registration of individual particles present in the prototype, and associated with the operation of the laser in a pulsed mode - with a small number of them without a preliminary start, tied to the excitation of particles upstream by another laser, or with their large number when there is a pre-trigger but the trigger rate is higher than the limit frequency set for the laser.

All of the above factors make it possible to significantly increase the efficiency of radiation collection and the information content of the optical signal, while simplifying the design of the optical system and the requirements for its maintenance.

As will be appreciated by those skilled in the art, the present invention can easily be developed in other specific forms without departing from the spirit of the present invention.

However, the present embodiments are to be considered merely illustrative and not limiting, and the scope of the present invention is represented by its claims, and it is intended that all possible changes and the scope of equivalence to the claims of the present invention are included.

Claims (12)

1. An optical system for determining the composition of aerosols based on the luminescent analysis of aerosol particles, containing at least one source of exciting radiation, with a sequentially placed focusing means for focusing the exciting radiation on a stream of aerosol particles, with a sequentially placed optical subsystem for transmitting optical signals from a stream of aerosol particles , as well as with a sequentially placed optical subsystem for the spectral separation of optical signals from a stream of aerosol particles, containing beam-splitting mirrors, as well as receivers of scattered and luminescent radiation with receiving areas, characterized in that LED sources are used as exciting radiation sources, the radiation of each of which is focused at one point of the aerosol jet using a focusing means consisting of a converging lens, a directing mirror and an aspherical lens, while the optical subsystem for transmitting optical optic signals from the flow of aerosol particles is made on the basis of an elliptical mirror and a spherical mirror, spatially separated from the area of the aerosol jet, and contains an optical return element configured to amplify the radiation intensity in the focus area of the LED sources, and at the output, the optical subsystem for transmitting optical signals from the flow aerosol particles contains a diaphragm located in the second focus of the elliptical mirror and a collimating lens, the focusing point of the LED radiation sources coincides with the focus of the spherical mirror and the first focus of the elliptical mirror, and the focus of the collimating lens is configured to form a parallel beam of scattered and luminescent optical signals from aerosol particles flow, coincides with the second focus of the elliptical mirror and the location of the diaphragm, while the optical subsystem of the spectral separation of optical signals from the aerosol particles flow contains a cutting filter installed after the first beam-splitting mirror, and a neutral filter installed in front of the scattered radiation receiver, while the light diameter of the optical and luminescent radiation beams coincides with the aperture of the receiving areas of the scattered and luminescent radiation receivers. 2. The optical system according to claim 1, characterized in that it contains two LED sources of exciting radiation, which are located opposite each other and have the same spectral range of radiation, while these LED radiation sources are focused using two guiding mirrors located at an angle to each other. to a friend, to one point of the aerosol jet. 3. The optical system according to claim 1, characterized in that it contains two LED sources of exciting radiation, of different spectral range, which are located at right angles to each other and are focused at one point of the aerosol jet using one directing mirror, while these LED sources radiation of different spectral ranges is used alternately, at the choice of the operator, depending on the tasks of luminescence analysis. 4. The optical system according to claim 1, characterized in that the optical subsystem for the spectral separation of optical signals from the flow of aerosol particles contains a rejector filter, which is installed after the cutoff filter, and is configured to cut off exciting radiation from the luminescent radiation receivers from the second LED source of exciting radiation . 5. The optical system according to claim 3, characterized in that the duration of the inclusion of each of the LED sources of exciting radiation of different spectral ranges correlates with the time spent by the aerosol particle in the jet in the analysis area. 6. The optical system according to claim 1, characterized in that the focusing means contains a bandpass filter placed between the collecting lens and the guiding mirror, while the bandpass filter is configured to correct the spectral composition of the excitation radiation of the LED source. 7. Optical system according to claim 1, characterized in that an elliptical mirror is used as an optical return element. 8. Optical system according to claim 1, characterized in that a parabolic mirror is used as an optical return element. 9. The optical system according to claim 1, characterized in that a photodetector is installed in the center of the optical return element, configured to control the power of the exciting radiation of each LED source of exciting radiation. 10. The optical system according to claim 2, characterized in that two spherical mirrors are used as two guiding mirrors, the focus of one of which coincides with the focus point of the LED sources of exciting radiation, and the focus of the second coincides with the location of the diaphragm. 11. Optical system according to claim 1, characterized in that the converging lens has a spherical surface. 12. Optical system according to claim 1, characterized in that the converging lens has an aspherical surface.

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