SU1385034A1 - Device for measuring sizes and account concentration of disperse particles - Google Patents

Abstract

The invention relates to a simulation technique for determining parameters of dust and gas flows, and can be used in the energy, metallurgy and other industrial sectors. The purpose of the invention is to improve the measurement accuracy by increasing the signal-to-noise ratio and eliminating the vignetting effect. A device for measuring the size and counting concentration of dispersed particles contains a light source optically connected to the first diaphragm, the first lens and the aspiration channel, the measuring channel containing the second diaphragm in series, the second lens reflecting a prism with a lateral rib parallel to the axis of the hub aspiration, two photodetectors mounted on the side edges of the reflective prism, an adder and an electronic key. In this case, the outputs of the photodetectors are connected to the inputs of the adder and the control inputs of the electronic key, the input of the adder is connected to the input of the electronic key. The goal is achieved by the fact that the second aperture, the second lens and the reflecting prism are mounted on the optical axis of the light source behind the aspiration channel, and the device is equipped with a correction channel containing successively installed additional aperture, an objective lens and a reflecting prism, as well as two additional photodetectors. At the same time, the optical axes of the additional aperture, the objective lens and the reflecting prism are installed perpendicular to the optical axis of the light source, and the outputs of the additional photodetectors are connected to the additional control inputs of the electronic switch. 1 hp f-ly, 1 ill. (L from 00 SP about with Olii

Description

This technique is used to determine the parameters of dust and gas flows, and can be used in the power industry5 metallurgy and other industrial sectors.

The aim of the invention is to improve the measurement accuracy due to the understanding of the photodetectors 8, 9, 13 and 14. The views of the photodetectors 8, 9 and 13, g 14 are divided into two equal parts by prisms 7 and 12, respectively, so that the prism 7 dividing line passed through the main optical axis of the first two photodetectors, and the line times

the increase in the signal-to-noise ratio and the disarray of the prism 12 passed through the main phase of the vignetting effect. The optical axis of the light source 1.

The drawing shows the function- Particle of the two-phase flow, the passage to the scheme of the proposed device. through a countable volume dissipates and

The device for measuring dimensions partially absorbs the probing radiation and the countable concentration of disperse particles for an hour to 15 hours. The intersection of a particle with a counting particle contains an optical system of volume in the insensitive region that leads to simultaneous influence of signals from photodetectors 8, 9, and 1 (in the absence of a signal from a photodetector 20) or from photodetectors 8, 9, and 13 (in the absence of a signal with a photo-

veteran, consisting of source 1: light, rectangular field diaphragm 2 and lens 3, aspiration channel 4, correcting optical system of photodetectors, consisting of lens 5, diaphragm 6, reflecting prism 7, photodetectors 8 and 9, measuring optical system of receiver 14). Only in the case of the intersection of a particle of a countable volume in the measurement region do the signals from all

receivers, consisting of a lens 5 photodetectors (8, 9 and 13, 14) in response to 10, aperture 11, a reflecting prism 12, photoreceivers 13 and 14, an adder 15 of an analog signal and a controlled electronic key 16. Side edges

simultaneously and recorded. In this case, the signals from the adder 15 pass through the electronic key 16 (the key is open when there are signals from all pho

reflecting prisms 17 and 12 are parallel to the axis of the aspiration channel 4, the optical axes of the optical system of the illuminator, photodetectors 8 and 9, and the axis of the aspiration channel 4 being mutually perpendicular and intersected in the center of the counting volume at one point. Two photodetectors 13, 14 are installed on both sides of the reflective prism 12, placed in the direction of the optical axis of the source 1 of the light behind the aspiration channel.

The outputs of each photodetector 8, 9 are connected to the control inputs of the electronic key 16, and the outputs of each photodetector 13, 14 are connected via an adder 15 to the input of the electronic key 16 and its control inputs directly.

The device works as follows.

The light emitted by the source 1, passing through the diaphragm 2, focuses the lens 3 in the region of the aspiration channel 4 so that the image of the diaphragm 2 is transferred to the intersection of the axis of symmetry of the aspiration channel 4 and. the main optical axis of the first system of photodetectors 8 and 9. Square diaphragms 6, 11, together with

receiver 14). Only in the case of the intersection of a particle of a countable volume in the measurement region do the signals from all

photodetectors (8, 9 and 13, 14) by ow -

simultaneously and recorded. In this case, the signals from the adder 15 pass through the electronic key 16 (the key is open when there are signals from all pho

receivers)

Claims (2)

1. Device for measuring the size and counting concentration of dispersed particles, containing a light source optically connected to the first diaphragm, first lens and aspiring channel, measuring channel containing the second diaphragm sequentially mounted, second lens, reflecting prism with a side edge parallel to the aspiration channel axis , two photodetectors mounted on the side edges of the reflecting prism, an adder and an electronic key, the outputs of the photodetectors being connected to the inputs of the adder and the control inputs The electronic key and the output of the adder are connected to the electronic key input, characterized in that (in order to improve measurement accuracy by increasing the signal-to-noise ratio, the second aperture, the second lens of the reflecting prism is mounted on the optical axis of the light source behind the aspiration channel . 2. The device according to claim 1, characterized in that, in order to improve measurement accuracy by eliminating the effect of vignetting, the device is equipped with a correction channel containing successively installed additional diaphragm, lens and reflecting prism, and 2 3 / t, Also, two additional photodetectors, the optical axes of the additional diaphragm, the lens and the reflecting prism are installed perpendicular to the optical axis of the light source, and the outputs of the additional photodetectors are connected to the additional control inputs of the electronic switch. 10 11