SU1226172A1 - Method of measuring concentration of aerosol dispersed phase - Google Patents

Abstract

The method of measuring the concentration of the dispersed phase of azrozole is designed to control the environment and improves the accuracy of measurement by providing the same modulation depth of the azrozole flow in a wide range of particle sizes. The method consists in that the particle flux density is modulated and density fluctuations are measured, the amplitude of which determines the concentration of the dispersed phase. The stream is periodically divided into the main and modulating in this section, the dispersed phase is filtered in the modulating stream and the purified gas is returned to the same predetermined section. At the same time, the main flow rate is kept constant, and the gas flow rate is set according to the calibration dependence. 1 il. c (b (L

Description

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The invention relates to a measurement technique, is intended to measure the concentration of aerosol particles, and can be used in monitoring pollution of the environment, mining, and other industries.

The aim of the invention is to improve the measurement accuracy by providing the same modulation depth of the aerosol flow over a wide range of particle sizes.

The drawing shows a functional diagram of the device for implementing the method.

The device contains a pipeline 1 of the initial stream and a pipeline 2 for sampling a stream of particles and returning the purified gas. The channels of the pipes 1 and 2 intersect each other and have, for example, the same rectangular cross-sectional shape and the same dimensions of the cross-section. In line 1, a sensor 3 for a concentration meter, for example, optical or induction, and a flow booster 4 are installed in series with the flow. In line 2, a circulation pump 5 and an aerosol filter 6 are installed in series. A successively selective amplifier 7 with a synchronous filter and indicator 8 are connected to the sensor 3, the control winding of the circulation pump 5 and the synchronization input of the amplifier 7 are connected to the output of the modulator 9.

The method is carried out as follows.

The flow booster 4 pumps the tested aerosol through the duct of the pipeline 1. The flow rate is kept constant with the aid of the flow impeller 4, and its value is determined from the conditions for providing isokinetic selection. When the circulating pump 5 is turned off, the speed, concentration of the dispersed phase and the dispersed composition of the aerosol practically do not change from the entrance of pipeline I to the measurement zone of sensor 3. When the circulation pump 5 is turned on, the modulator 9 controls the initial flow of the aerosol or a part the flow is taken to the duct of the pipeline 2, passes through the circulation pump 5, is cleaned of aerosol particles in the filter 6 and re-enters the duct of the pipeline 1. Since

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five

0 5 0

0 5 0 5

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the volume of aerosol collected from pipeline 1 is equal to the volume of filtered gas returned to it. Any changes in the flow rate in the pipeline 2 do not cause a change in the flow-rate in the pipeline 1 and, thus, do not cause a change in its hydrodynamic resistance and the speed of the initial flow. With LLP% modulation, the flow rate in pipe 2 is set by the circulation pump 5 at a higher flow rate of the initial flow, which prevents the overshoot of large particles with a longer relaxation time through the intersection zone of pipelines 1 and 2. At high concentrations, the flow rate of the circulation pump 5 can decrease by decreasing flow rate in pipeline 2, in this case, the modulation depth is determined by the ratio of flow rates in pipelines 1 and 2. By selecting the cross section of pipelines 1 and 2, it is possible to provide time for particles to pass through the intersection zone of the pipe rovodov greater than the relaxation time of a predetermined size of particles, thereby to provide a uniform depth of modulation of the particle flux density in a wide range of sizes at a desired modulation depth value. one

When the circulating pump 5 is running, the filtered gas or diluted aerosol with an undistorted particle size distribution spectrum enters the measurement zone of the sensor 3. When the pump 5 is turned off, an aerosol with the initial concentration of the dispersed phase enters the measurement zone. Thus, a modulated aerosol flow passes through the measurement zone of sensor 3, causing a periodic signal at its output with a frequency determined by the modulator 9. The variable component of the signal is extracted by amplifier 7, synchronized with 1m pulses of modulator 9. The use of synchronous signal extraction allows a high value of the signal-to-noise ratio. The amplitude of the signal at the output of the selective amplifier 7, proportional to the concentration of the dispersed phase of the aerosol, is recorded by the indicator 8.

Claims (1)

Invention Formula A method for measuring the concentration of the dispersed phase aerosol, concluded with that the particle flux density is modulated and the density fluctuations are measured, the amplitude of which determines the concentration of the dispersed phase of the aerosol, which is such that, in order to improve the measurement accuracy by providing the same modulation depth of the aerosol flow over a wide range of particle sizes, periodically divide the flow of particles into the main and modulating given its cross section, filtering the dispersed phase in the modulating flow and return the purified gas to the same predetermined cross section, at. In this case, the main flow rate is kept constant, and the gas flow rate in the modulating flow is set according to the calibration dependence in the range from zero to the value exceeding the main flow rate. Editor S.Patrusheva Compiled by D. Gromov Tehred V. Kadar Order 2116/34 Draw 778 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 Production and printing company, Uzhgorod, st. Design, D Corrector S.Cherni