RU2329486C2 - Laser device to control quality of dispersing liquid with sprayers - Google Patents

Abstract

FIELD: optics.

SUBSTANCE: invention refers to examination or analysis of materials by means of optical devices in a fluid medium, particularly to the structure of optical devices designed to quantitative assessment of dispersing liquid with sprayers. The device contains three lasers, optical generators of emission flat flows, coloured TV camera and a computer. The TV camera contains photosensitive components of three kinds, the first of which possesses maximum of spectral sensitivity in a red spectral region, the second has a maximum spectral sensitivity in a green spectral region, and the third possesses maximum spectral sensitivity in a blue spectral region. The length of a wave of the first laser corresponds to maximum spectral sensitivity of photosensitive components of the first kind of the coloured TV camera; the length of a wave of the second laser emission corresponds to maximum spectral sensitivity of photosensitive components of the second kind of the coloured TV camera, and the length of a wave of the third laser emission corresponds to maximum spectral sensitivity of photosensitive components of the third kind of the coloured TV camera connected to interface unit generating three digital representations in the computer; the said representations correspond to red, green and blue colours. At that an optical axis of the coloured TV camera is aligned with the axis of symmetry of the sprayer; the emission flow of a blue colour passes through a top of a nozzle end of the sprayer, while emission flows of a red and green colour are set off the said top at some distance.

EFFECT: upgraded reliability of quality control at dispersing liquid with spayers and reduction of errors at measurement of geometric parameters of a space distribution of sprayed particles.

1 dwg

Description

The invention relates to the field of research or analysis of materials using optical means in a fluid stream, and more particularly to the design of optical devices for the quantitative assessment of atomization of liquids by nozzles. It can be used to control and test nozzles for various purposes.

Known laser devices for the quantitative assessment of the quality of liquid atomization by nozzles described in the book (Zhuravlev O.A., Medinskaya L.N., Shorin V.P. Laser diagnostics of two-phase flows. - Kuibyshev: Institute of Kuib. Aviation Institute , 1989. - 74 pp.) And based on the use of laser Doppler anemometry and small-angle light scattering. In a laser Doppler anemometer, the measuring volume in the stream of particles sprayed by the nozzle is formed by two interfering laser beams. Thus, the measuring volume is a local area in space filled with interference fringes. The particle sprayed by the nozzle, crossing in its movement the interference bands filling the measuring volume, becomes a source of scattered light of variable intensity. The amplitude and frequency analysis of this intensity allows you to calculate the concentration and speed of particles in the measuring volume.

Devices based on the use of small-angle scattering also involve the formation of a local light region - the measuring volume - in the particle stream and analysis of the angular distribution of the light scattered by the sprayed particles, based on which the concentration of particles in the measuring volume is calculated.

A disadvantage of the known devices when measuring the geometric parameters of the spatial distribution of the sprayed particles is the need to scan a small measuring volume over the spatial region within which the spatial distribution of the sprayed particles is investigated. The set of geometric parameters of the spatial distribution of the sprayed particles makes up a set of quantitative indicators of the quality of liquid atomization by the nozzle. In addition, the time spent on scanning limits the scope of known devices based on the use of laser Doppler anemometry and small-angle light scattering by measurements of stationary spatial distributions.

The closest technical solution is a laser device for monitoring the quality of fuel atomization and determining the geometric parameters of the jets of a diesel nozzle (RF Patent No. 1759138, M., CL G01N 21/47, publ. 05.20.1999). The device contains a laser, the beam of which, using a system of mirrors, is divided into two beams entering the optical formers of plane radiation fluxes. Flat radiation fluxes are oriented perpendicular to the nozzle axis and pass over the nozzle tip of the nozzle, the first plane passing through the tip of the nozzle tip to fix the center of symmetry of the pattern, and the second at a known distance from the first, determined from the condition of obtaining two separate sections of the jets. The light scattered by the particles of the sprayed liquid falling in the plane of the radiation fluxes is recorded by the camera, and images of the spatial distributions of the cross sections of the particle field emitted by the flat radiation fluxes are visualized on the television receiver with a transparent template on which the admissible sizes of the jets with the tolerance field are indicated, and at the same time in a computer for calculating a set of geometric parameters of the spatial distribution of atomized particles. The control and rejection of nozzles is performed either by comparing the visualized images with a template, or by a set of geometric parameters of the spatial distribution of atomized particles calculated using a computer.

The known device has the following disadvantages: it is necessary to select the distance between plane radiation fluxes from the condition of obtaining two separate sections of the jets, because device operation is possible only with separate images of these sections on one fixed and processed frame; using the first light plane to simultaneously fix the center of symmetry of the pattern coinciding with the tip of the nozzle tip of the nozzle and the first section of the jet, which can be small in geometric dimensions near the tip of the nozzle tip of the nozzle, as a result of which the measurement of the geometric parameters of the first section of the jet in the image will be burdened by large errors.

The basis of the invention is the task to increase the reliability of the quality control of atomization of liquid by nozzles and to reduce the error in measuring the geometric parameters of the spatial distribution of the sprayed particles.

This problem is solved due to the fact that in the laser device for controlling the quality of liquid atomization by nozzles containing a laser, optical formers of flat radiation fluxes, a camera and a computer, according to the invention, a color camera is installed containing three photosensitive elements, the first of which has a maximum spectral sensitivity in the red spectral region, the second has a maximum spectral sensitivity in the green region of the spectrum, the third has a maximum spectral sensitivity in s region of the spectrum, two lasers were additionally introduced, the wavelength of the first laser corresponding to the maximum spectral sensitivity of the photosensitive elements of the first type of color camera, the radiation wavelength of the second laser corresponding to the maximum of the spectral sensitivity of photosensitive elements of the second type of color camera, the radiation wavelength of the third laser corresponds to the maximum of spectral sensitivity photosensitive elements of the third type of color camera, and device voltages, forming in a computer three digital images corresponding to red, green and blue.

The introduction of a color television camera with three types of photosensitive elements, matched with them according to the spectral sensitivity of the lasers, and a coupler, which forms three digital images in the computer that correspond to red, green and blue, allows using one of the lasers to visualize the nozzle tip, and at the same time distribution of sprayed particles in the near-nozzle region, by displacing two other lasers with corresponding shapers of plane radiation fluxes relative to the first and each other, we optimize to create a scheme for measuring the spatial distributions of sprayed particles according to the criterion of the minimum measurement errors of a particular geometric distribution parameter, regardless of whether the images of all three sections overlap each other in the image frame or not, because images of red, green and blue colors, firstly, correspond to each well-defined section and, secondly, they can be processed by computers independently of each other.

The drawing shows a diagram of a laser device for controlling the quality of liquid atomization by nozzles.

The device contains three lasers, the first of which 1 generates in the green region of the spectrum, the second 2 in the red and the third 3 in the blue, with the beam of each of the lasers, the shapers of plane radiation fluxes 4, 5 and 6 are optically coupled; a color camera 7 containing photosensitive elements of three types, the first of which has a maximum spectral sensitivity in the red region of the spectrum, the second has a maximum of spectral sensitivity in the green region of the spectrum, the third has a maximum of spectral sensitivity in the blue region of the spectrum; the interface device 8, forming in the computer 9 three digital images corresponding to red, green and blue colors; the nozzle 10 connected through the hydraulic pipe 11 to the hydraulic pump 12. The optical axis of the color camera 7 is aligned with the axis of symmetry of the nozzle 10. The planes of the flat radiation fluxes of green 13, red 14 and blue 15 colors are perpendicular to the axis of symmetry of the nozzle 10, and the blue radiation flux 15 passes through the tip of the nozzle tip of the nozzle 10, and the radiation fluxes of the red 14 and green 13 colors are offset by some distance relative to the top of the nozzle hole of the nozzle in accordance with the objectives of a particular experiment. The number 16 conventionally indicates the particles of the atomized liquid indicating the direction of their movement.

The device operates as follows. Using a hydraulic pump 12, a nozzle 10 is sprayed with liquid through a hydraulic pipe 11. Particles of the sprayed liquid 16 falling in the plane of the radiation flux scatter light that is detected by a color camera 7. The output signal of a camera is digitized by an interface device 8, which forms three digital images in computer 9, corresponding to blue, red and green colors. The blue digital image determines the coordinates of the center of symmetry of the nozzle and the spatial distribution of droplets of the sprayed liquid in the nozzle area. The red digital image determines the spatial distribution of particles at a predetermined distance from the nozzle tip of the nozzle. The green digital image determines the spatial distribution of particles at an even greater distance from the nozzle.

A comparison of the coordinates of the center of symmetry of the nozzle with the coordinates of the energy center of the red and green images gives an idea of the symmetry of the spatial distribution of atomized particles. Changing the geometric dimensions during the transition from a red image to a green one at known distances between light sections allows one to determine the spatial shape of the spray torch and the volume filled with sprayed particles.

The sequence of arrangement of light planes of blue, red and green colors with respect to the nozzle tip of the nozzle is selected from the condition for obtaining sufficiently bright images in all three colors and therefore may differ from that shown in the drawing. To satisfy the conditions for obtaining sufficiently bright images in all three colors, one should take into account the radiation power of each laser, the change in the light scattering coefficient by the droplets of the sprayed liquid when moving from the blue region of the spectrum to green and red, and the decrease in the concentration of scattering centers — drops — with distance from the nozzle tip nozzles and changes in the spectral sensitivity of a color camera.

The sequence of light planes of blue, red and green colors with respect to the nozzle tip of the nozzle shown in the drawing is selected for reasons of consistency of the spectral sensitivity of color cameras with the visibility curve of the human eye. The sensitivity of the human eye, and therefore the color camera, is greatest in the green region of the spectrum, in the red and blue regions it is significantly less. The concentration of atomized particles per unit volume with distance from the nozzle tip of the nozzle decreases, therefore, the concentration of scattering centers per unit area of a plane radiation flux also decreases. If the emission powers of blue, red, and green lasers are the same and the scattering coefficient of light by the sprayed particles also does not change much in the visible range, then the sequence of arrangement of light planes of blue, red, and green colors shown in the drawing takes into account changes in the concentration of sprayed particles with distance from the nozzle and spectral sensitivity color camera, which allows you to get approximately equally bright images in all three colors.

Claims (1)

A laser device for controlling the quality of liquid atomization by nozzles, including a laser, optical formers of plane radiation fluxes, a television camera, and a computer, characterized in that a color camera is installed that contains three photosensitive elements, the first of which has a maximum spectral sensitivity in the red region of the spectrum, the second has a maximum spectral sensitivity in the green region of the spectrum, the third has a maximum spectral sensitivity in the blue region of the spectrum, additionally introduced a laser, and the wavelength of the first laser corresponds to the maximum spectral sensitivity of the photosensitive elements of the first type of color camera, the wavelength of the radiation of the second laser corresponds to the maximum of the spectral sensitivity of photosensitive elements of the second type of the color camera, the radiation wavelength of the third laser corresponds to the maximum spectral sensitivity of the photosensitive elements of the third type of the color camera connected to the interface device forming in the computer three The digital images corresponding to red, green and blue, with the optical axis of a color television camera is aligned with the axis of symmetry of the nozzle, the flow of blue radiation passes through the top nozzle injector tip and radiation fluxes of red and green colors are shifted by some distance from said vertex.