RU2155954C2 - Process of distant test of mass concentration of finely dispersed aerosols of toxic agents by their inherent luminescence at locations of storage and destruction of toxic agents with emergence of unusual conditions - Google Patents

Abstract

FIELD: optical methods of measurement of physical and chemical characteristics of aerosol atmosphere. SUBSTANCE: technical objective of invention lies in development of process of distant test of mass concentration of finely dispersed luminescent aerosols of toxic agents independent of size of aerosol particles against background of unintentional impurities. In correspondence with invention laser sounding with ultraviolet radiation with wave length λ= 266 nm, recording of background characteristics (I_b) of atmosphere and intensity (I_l) of luminescence signals of aerosol of toxic agent in spectrum region 300-440 nm are conducted. Amplitude of luminescence signal is normalized to amplitude of signal of combination of dispersion of nitrogen of air

on wave length λ=284 nm and preliminary calibration of sounding equipment to finely dispersed fraction of aerosol is conducted. Intensity (I_d) of signals of backward dispersion at wave length of sounding radiation is recorded to exclude influence of presence of unintentional impurities on results of sounding. EFFECT: enhanced efficiency of process of distant test of mass concentration of finely dispersed aerosols of toxic agents independent of size of their particles. 1 cl, 3 tbl

Description

 The invention relates to the field of optical methods for measuring the physicochemical characteristics of aerosol media and can be used in the development of remote means of technical control (TC) of concentrations of aerosol clouds of luminescent toxic substances (OM) for assessing the consequences of emergency situations in the places of storage and destruction of OM.

 Compared with local methods for monitoring the parameters of aerosol clouds, optical methods have several advantages (the ability to control the dynamics of cloud propagation, high speed, wide territorial coverage, etc.), which makes them promising in the interests of monitoring objects for storage and destruction of OM. At present, various methods for remote monitoring of both the dispersed composition of the indicated aerosol cloud of OM and the concentrations of aerosol particles in the cloud have been proposed.

 So, for example, there is a method for remote monitoring of concentrations and average particle size of atmospheric aerosol, based on the registration of electromagnetic radiation scattered in the region of diffraction angles (Van de Hulst G. Light scattering by small particles. - M .: IL, 1961). The proposed method has several disadvantages due to the bistatic sensing scheme, which allows it to be used only in laboratory conditions or in closed test complexes.

 There are also known methods and methods for remote monitoring of the microphysical parameters of atmospheric aerosol, based on the method of multi-frequency laser sensing (Krekov G.M. Methodological issues of laser sensing of the molecular and aerosol atmosphere. // Remote methods for studying the atmosphere. / Ed. Zueva V.E. - Novosibirsk: Nauka, 1980). The use of multi-frequency sounding provides for registration of relative intensities of backscattering signals and restoration of aerosol cloud parameters using complex algorithms that are difficult to implement in practice.

 Closest to the technical nature of the claimed method is a method for remote control of the mass concentration of aerosols and gases in the atmosphere, disclosed in the application DE 4309417 A1, G 01 N 21/25, 04/14/94. This method involves monitoring the air surrounding the Earth using a device on laser diodes placed on an aircraft. The principle of operation of the device is to measure the trace amounts of gases and aerosols falling into an open Harriott cell when the aircraft is moving, based on laser radiation and a system of detectors. The above method is of little use for measuring the parameters of OM aerosol clouds, since it involves contact between the device and the aircraft with the air contaminated with OM and the need for degassing of complex equipment after each measurement. The second significant drawback of this method is that it does not have spatial resolution and can only measure the volume of air that enters the Herriott cell. This method can be used to solve the problems of identifying the environmental situation in safe areas.

 However, the analysis of information materials shows that the phenomenon of stimulated luminescence of OM aerosols when excited by ultraviolet laser radiation in the case of expanding the amount of spectral information and improving the processing algorithms of remote sensing data can be used to solve the problems of controlling OM aerosols. In particular, a very urgent problem of technical control for predicting the consequences of disruption of technological processes is the determination in natural conditions of concentrations of aerosol particles of OM in the clouds, which can be formed during emergency situations at the facilities for storage and destruction of OM. Based on the physicochemical properties of the aerosols, it is clear that the finest dispersed non-settling aerosol, which can spread over long distances, is the most dangerous. The formation of a fine aerosol is favored by most of the proposed technologies for the destruction of organic matter, which are based on the use of high temperatures, pressure, as well as the production of explosive and fire hazardous products of organic matter destruction. The development of technical means for monitoring the concentrations of aerosol particles with a diameter d <10 μm based on local sensors is a difficult task, and therefore the implementation of remote methods for measuring the aerosol cloud microstructure is a promising area of research.

где I_л - сигнал люминесценции аэрозоля ОВ;
I_ф - сигнал фона;

- сигнал комбинационного рассеяния азота воздуха;
K - калибровочный коэффициент.The studies showed that when probing clouds of luminescent aerosols with a particle size d <10 μm, the luminescence intensity mainly depends on the mass concentration of particles and practically does not depend on their size. Therefore, by pre-calibrating the lidar complex for a specific type of organic matter, it is possible to estimate the mass concentration of organic particles from the location of the cloud. In order to exclude the influence of the parameters of the equipment on the sensing results, it is advisable to normalize the amplitude of the OB aerosol luminescence signal to the amplitude of the Raman signal of air nitrogen molecules, the concentration of which in the atmosphere is constant. Subject to the above conditions, a simple expression can be used to control the mass concentration (C _m ) of finely divided aerosols of OM:

where I _l is the luminescence signal of aerosol OM;
I _f - background signal;

- signal of Raman scattering of nitrogen;
K is the calibration factor.

 To take into account the influence of meteorological conditions on the control results, before each experiment, the background atmospheric characteristics are measured, which are taken into account when calculating OM aerosol concentrations using formula (1).

 As a rule, one of the difficult problems of remote control is the effect on the measurement results of the presence of interference aerosols on the sensing path (dust, smoke, soot, etc.). An analysis of the possibilities of using luminescent lidars in the interests of technical control shows that it is possible to eliminate the influence on the experimental results of the luminescence of interfering aerosols by deciphering the information contained in the signal of back aerosol scattering. Our preliminary experiments showed that the ratio of the luminescence signal to the light scattering signal of the aerosol OM more than an order of magnitude different from the same ratio for interfering impurities. This phenomenon can be used to increase the noise immunity of the method in cases accompanied by a significant emission of interfering impurities into the atmosphere (dust, smoke, soot, etc.).

 The objective of the present invention is to develop a method for remote control of the mass concentration of finely dispersed luminescent aerosol ОВ (d≤10 μm) regardless of the size of aerosol particles against interfering impurities (dust, smoke, soot, etc.) to predict an emergency situation in case of an emergency at the facilities of storage and destruction of OM.

 An example implementation of the method.

The stated object is achieved in that the sensing aerosol cloud OB performed by laser radiation with a wavelength λ = 266 nm ^(4th harmonic of YAG laser), and register the luminescence spectrum of the aerosol produced in the OB region 300 ... 440 nm. Simultaneously with the registration of the maximum luminescence intensity, a measurement of the signal intensity of Raman scattering of air nitrogen at a wavelength of λ = 284 nm is carried out. Aqueous solutions containing luminescent additives were used as a simulation formulation of type Vx OM. In this case, to ensure the identity of the experimental results, a necessary condition was the equality of the quantum yields of the luminescence of organic matter and its simulation formulation. Before the start of field trials, the lidar complex was calibrated according to the selected type of simulation formulation. In this case, the value of the calibration coefficient included in expression (1) was found as the average value when conducting a series of calibration experiments with different values of the aerosol concentration in the model cloud of organic matter.

Simultaneously with measurements of the luminescence intensity and Raman scattering of air nitrogen, the aerosol scattering intensity was recorded at the probe radiation wavelength λ = 266 nm. A movable Raman-luminescent lidar (PCLL), placed on the chassis of the Ural-375K car, was used as a TK remote control. Lidar had the following main technical characteristics:
The radiation wavelength, nm - 266
Laser pulse power, kW - 30
Laser pulse duration, ns - 10
The pulse repetition rate, Hz - 12.5
Diameter of a receiving mirror, mm - 360
The number of gates, pcs - 32
Power consumption, kW - 4
The tests were carried out on clouds of simulated OM formulations created in a 22 m long field chamber using three aerosol generators. At the second stage of testing, cluster elements were used to create model clouds of simulator aerosols. Sensing range was:
210 m - when carrying out work using a field aerosol chamber;
500 m - when the simulator is transferred to an aerosol state by group detonation of cluster elements.

 The concentration and dispersed composition of the OM model cloud were monitored using simulators and AFA-B-10 filters, followed by analysis by the chemoluminescent method on the Lyubitel instrument.

 Table 1 presents the results of a comparative assessment of two methods for controlling particle concentrations in a model OM cloud. When calculating the relative errors of the experiments, the measurement results obtained using local control means were taken as the true concentration values.

 Table 2 presents the results of the second test stage, in which the conversion of the OM simulator to the aerosol state was carried out by detonating the cartridge elements.

 At the same time, in the course of these studies, the possible impact on the results of remote monitoring of the presence in the atmosphere of aerosols of impurities that could be formed in the event of an emergency at the facilities for the storage and destruction of OM was evaluated.

 Table 3 shows the results confirming the selection of useful signals due to additional information contained in the backscattering signals.

.An analysis of the data presented in table 3 shows that despite the higher concentration of interfering aerosols (C = 10 ^-1 ... 10 ^-2 mg / l) compared with the concentration of the Vx type OM simulator (C = 10 ^-4 mg / k), the ratio of the luminescence signal (λ = 335 nm) to light scattering (λ = 266 nm) for the simulator cloud is more than an order of magnitude higher than the similar ratio for interfering aerosols. In connection with the foregoing, this feature can be used to select useful signals against interfering impurities. The solution to this problem is especially relevant in an emergency accompanied by fire, explosions, when the shielding effect of interfering aerosols - dust, smoke, explosion products, etc. can significantly affect the results of remote control. The generalized criterion by which one can judge the presence of OM in the atmosphere of the aerosol and the practical absence of interfering impurities can be considered the fulfillment of the condition

.

 If the conditions for single scattering are met, that is, when the screening effect of interfering aerosols is insignificant, the presence of impurities should not affect the results of measuring the concentration of OM of type Vx in connection with their insignificant contribution to the total luminescence of the cloud. Therefore, an increase in the relative experimental error to 74.4% (see Table 2) during tests using cassette elements can be explained by the presence of a large number of particles in a cloud with a diameter d <10 μm. In this case, the coefficient K in formula (1) can significantly differ from its values obtained when calibrating the lidar using a field aerosol chamber, which introduces additional errors in the measurement results.

 The proposed method for remote control of the microstructure of luminescent OM allows controlling the dynamics of changes in the concentration of aerosol particles, measuring the spatial and geometric dimensions of the cloud with high resolution (taking into account the capabilities of the domestic element base, spatial resolution in the area of up to 3.75 m can be achieved). The method can be applied to control the parameters of coarse-dispersed OM clouds provided that the lidar complex is pre-calibrated by OM aerosol clouds of a given dispersed composition.

 The analysis of the spectral characteristics of batches of Vx-type OM with different storage periods, initial products of the synthesis of organic matter, and also intermediate volatility showed that the proposed method can be successfully applied in the interests of controlling an extensive list of organic matter.

Claims (2)

1. A method for remote control of the mass concentration of finely divided aerosols of toxic substances (OM) by their own luminescence in the places of storage and destruction of OM in case of emergency, including laser sounding with ultraviolet radiation with a wavelength of λ = 266 nm, registration of background atmospheric characteristics (I _f ) and luminescence signal intensities (I _k) aerosol OM in spectral region 300 - 440 nm, characterized in that to eliminate the influence of the aerosol formulation dispersed agents and equipment parameters to Reza taty sensing performed normalization luminescence signal amplitude to the amplitude of the Raman signal of atmospheric nitrogen

at a wavelength of λ = 284 nm, and preliminary calibration of sounding equipment is carried out using finely divided aerosol fractions with a particle diameter d ≤ 10 microns. 2. The method according to claim 1, characterized in that to exclude the effect on the sounding results of the presence of interfering aerosols in the atmosphere (combustion products, explosion), the intensity of the backscattering signals (I _p ) is recorded at the wavelength of the probe radiation and if the condition

judge about the absence of interference impurities on the sensing path, but by the ratio

determine the mass concentration (C _m ) of a fine aerosol of luminescent OM.

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