DE19724228A1 - Method for measuring size distribution, optical characteristics or particle concentration - Google Patents

Abstract

Involves irradiating light perpendicularly to defined volume of flow and using rotating mirror to collect scattered light for detection

Description

With scattered light measurements on particles or particle collectives Concentrations and size distributions of particles in a carrier medium detected. This is based on the Mie theory (/ 1 /, / 2 /, / 6 /) for geometrically simple shaped particles predictable spatial Scattered light intensity distribution. To get to the particle parameters above To be able to close / 7 / must be at many scattering angles, if possible at the same Time, the light intensity can be measured. Objective of the present compact scattered light measuring device is to be as complete as possible Scattering matrix / 1 / the scattered light intensity at all angles between 0 ° and 180 ° to measure online and from it the size distribution and optical To determine the material properties of a particle collective.

The particle collective is irradiated with light, preferably laser light, whereby the light can be horizontally and vertically polarized or unpolarized. The Light sources should be able to be electrically modulated. The scattered from the particles The light is mounted to the scattering volume, rotatably and rotating mirror element deflected. The angle of the reflective surface is adjusted so that the scattered light is deflected perpendicular to the plane of rotation is, or it is redirected so that the circle that the scattered light forms, at a finite distance on the axis of rotation, approximately to one Point contracts. The reflective surface is either designed so that it deflects only a limited range of scattering angles or one in front of the surface Aperture installed, which limits the deflected scattering angle range. In the The beam path of the scattered light can have two polarizers in each Half plane (for example a polarizer in the angular range 0 ° to 180 ° and the second in the range 180 ° to 360 °). Another one The scattered light is directed onto a detector by means of a mirror and possibly a collecting optics redirected. The laser light is modulated in a binary sequence so that the signal of the scattered light with a matched filter / 4 / with a improved signal-to-noise ratio can be determined. The binary consequences  / The states of the two laser light sources can be selected so that they are not can be controlled in succession, but controlled in parallel with these sequences can be (code multiplex). To do this, these consequences must be chosen be that the cross-correlation functions between the signal of the Modulation sequence of one laser and the filter to the other laser is as weak as possible. To drift parameters of light sources, detectors and To compensate for amplifiers and pollution Scattered light intensity distribution normalized to a scattering angle.

Known technical solutions

State of the art is to view the particles at a variety of discrete angles to irradiate and the scattered light intensity even under a variety of discrete Detect angles (DE 38 13 718 A1, DE 43 34 208 A1, DE 44 14 166 C1, / 8 /). What is being attempted to meet the demand that the Scattered light intensities at as many angles as possible Particle characterization must be used. Because of the The number of possible scattering angles is limited. On the other hand, on a laboratory scale, it is common to have a detector on one Turntable in a light-tight chamber to turn around the scattering volume, so that the resolution of the scattered light distribution is continuous or can be measured quasi-continuously (/ 3 /, / 7 /, / 9 /). The beam of light from the incident light is chopped mechanically or electrically, so that the Detected scattered light intensity amplified by a lock-in amplifier and for Measured value evaluation can be fed to a computer.

Advantages of the invention

The advantages of the procedure are:

• - It has considerably less and lighter and only passive movable Components, so that due to the lower inertia measurement runs during the Duration of a particle in the scattering volume can be realized and thereby fluctuations in the scattered light intensity distribution Changes in concentration prevented during a measurement run.
• - The scattered light intensity distribution and the degree of polarization can be continuous or measured quasi-continuously under any scattering angle and at anisotropic particles can determine the scattering matrix at any angle will.  
• - The detector can be permanently installed in one place, which is particularly the case It is advantageous if a photomultiplier is used for the detection.
• - It is compact and portable and the particles can be characterized on-line will.

Field of application of the invention

The measuring method can be used in climate / environmental measuring technology for Field measurements of the particle parameters in air and (waste) water at which Exhaust gas measurement technology to determine the dust concentration and -Composition and in all process steps in which fine-grained Mixed or bulk goods are used, such as cement and glass production, to monitor the composition and / or emissions.

Embodiments Example 1 ( picture 1 and 2)

The particle-containing medium is fed to the device via the particle inlet tube 14 and suctioned off via the particle outlet tube 15 . About the common axis (rotation axis 17) of inlet 14 and outlet tube 15 rotates a disk 22 on which a mirror segment 6 is mounted at an angle of 45 ° to the plane of rotation 18 around the scattering volume. 5 A light beam 19 is directed from the light source 1 , preferably a laser, onto the scattering volume 5 . The scattering volume 5 is located at the intersection of the axis of rotation 17 and the light beam 19 . The scattering volume 5 is determined by the beam diameter of the light beam 19 and the diameter of the particle stream in the scattering volume 5 . The light scattered by the particles in the plane of rotation 18 in the angular range 0 ° to 360 ° is deflected by the rotating mirror segment 6 perpendicular to the plane of rotation 18 , with the exception of the angular ranges in which the mirror segment 6 passes through the light beam 19 . The scattered light 8 is again with the aid of a flat mirror 9 , which is at an angle of 45 ° to the axis of rotation in the beam path of the scattered light 8 and is at least large enough to cover the entire circle that the scattered light 8 can produce deflects the detector 11 by 90 °. A collecting optics 10 focuses the scattered light onto a light-sensitive detector 11 . The light beam 19 strikes a light trap 3 behind the scattering volume 5 . The signal from the detector is preamplified 23 and fed to the matched filter 24 . Before the A / D conversion 28 , the signal is adapted to the measuring range of the A / D converter 28 with the amplifier 26 . The digitized signal is fed to a computer 30 . The computer 30 controls the modulator and the control 31 of the light source 1. The modulation signal 33 is fed to the matched filter 24 . The measurement signal 35 is normalized to a fixed angle and evaluated in the computer 30 . The light beam 19 is switched off when the mirror segment 6 passes.

Example 2 ( picture 3 and 4)

The particle-containing medium is passed through the flow-through cell 16 . The axis of symmetry of the flow-through cell 16 is the axis of rotation 17 of the disk 22 . A mirror segment 6 rotates around the flow volume 16 around the scattering volume 5 . From the light sources 1 and 2 , preferably horizontally and vertically polarized laser light and preferably arranged close to one another, light beams 20 and 21 are directed onto the scattering volume 5 . The scattering volume 5 is located at the intersection of the axis of rotation 17 and the light beams 20 and 21 . The scattering volume 5 is determined by the beam diameter of the light beams 20 and 21 and the inner diameter of the flow cell 16 . The mirror segment 6 is mounted at an angle of more than 45 ° to the plane of rotation 18 such that the circle formed by the light 8 scattered by the particles contracts at a finite distance 37 on the axis of rotation 17 approximately to a point. The mirror segment 6 is covered by an aperture 7 , so that the deflected scattering angle range can be easily adjusted to the desired width. In the beam path of the scattered light 8 there is a filter 12 in the angular range 0 ° to 180 ° which only allows horizontally polarized light to pass through and in the angular range 180 ° to 360 ° there is a filter 13 for vertically polarized light. The scattered and filtered light 8 is again with the aid of a flat mirror 9 , which is at an angle of 45 ° to the axis of rotation 17 and is at least large enough to cover the entire circle that the scattered light 8 can generate in the direction of the detector 11 deflected by 90 °. The light beams 20 and 21 strike the light traps 3 and 4 behind the scattering volume 5 . The signal from the detector is preamplified 23 and fed to the matched filters 24 and 25 . Before the A / D conversion 28 and 29 , the signals are adapted to the measuring range of the A / D converter 28 and 29 with the amplifiers 26 and 27 . The digitized signals are fed to a computer 30 . The computer 30 controls the modulators and the controls 31 and 32 of the light sources 1 and 2 . The modulation signal 33 is the signal-matched filter 24 and the modulation signal 34 is fed to the signal-matched filter 25 for optimal signal evaluation. The measurement signals 35 and 36 are standardized and evaluated in the computer 30 to a fixed angle. 0 ° to 180 °, the horizontal stray light component of the horizontal beam 20 and in the angular range 180 ° to 360 ° the rotated vertical stray light component of the horizontally polarized light beam 20 is determined in the angular range from the measurement signal 35th 0 ° to 180 ° the rotated horizontal stray light component of the vertical beam 21 and in the angular range 180 ° to 360 °, the vertical stray light component of the vertically polarized light beam 21 is determined in the angular range from the measurement signal 36th The light beams 20 and 21 are switched off when the mirror segment 6 passes.

similar writings
DE 38 13 718 A1
DE 43 34 208 A1
DE 44 14 166 C1

literature
/ 1 / Bayvel, LP: Electromagnetic scattering and its applications, Appl. Science Publishers, London, 1981
/ 2 / Born, M .: Optik, Kapitel Metalloptik, Springer, Berlin, 1965
/ 3 / Dyja, H .: Experimental and theoretical investigations of a measuring system for determining the radiation scattered by particles, University of Duisburg, 1984
/ 4 / Hänsler, E .: Fundamentals of the theory of statistical signals, Springer Verlag, Berlin, 1983
/ 5 / Ishimaru, A: Wave propagation and scattering in random media, Academic Press, New York, 1978
/ 6 / Mie, G .: Contributions to the optics of cloudy media, especially colloidal metal solutions, Ann. d. Physics, 25, 377-445, 1908
/ 7 / Pinnick, RG: Polarized light scattered from monodisperse randomly oriented nonsperical aerosol particles, App. Optics, Vol. 15, No. 2, 384, 1976
/ 8 / Wyatt, PJ: Aerosol particle analyzer, App. Optics, Vol. 27, No. 2, 217, 1988
/ 9 / Burns, M .: Laser spectrophotometer for measuring differential cross sections of biological particles, App. Optics, Vol. 15, No. 3, 1976

Reference list

1

Light source

2nd

Light source

3rd

Light trap

4th

Light trap

5

Scattering volume

6

Mirror segment

7

cover

8th

scattered light

9

mirror

10th

Optics

11

detector

12th

Polarizing filter

13

Polarizing filter

14

Particle inlet tube

15

Particle outlet pipe

16

Flow cell

17th

Axis of rotation

18th

Plane of rotation

19th

incident light beam

20th

horizontally polarized light beam

21

vertically polarized light beam

22

rotating disc

23

Preamplifier

24th

filter

25th

filter

26

amplifier

27

amplifier

28

A / D converter

29

A / D converter

30th

computer

31

Light modulator and control

32

Light modulator and control

33

Modulation signal

34

Modulation signal

35

Measurement signal

36

Measurement signal

37

Intersection

Claims (8)

1. A method and device for measuring the size distribution, optical properties and / or concentration of particles or particle collectives in carrier media in flow cells or open particle streams by detecting the scattered radiation at different scattering angles, characterized in that

• a) an electrically modulated light source irradiates the particles perpendicular to the particle flow in a spatially limited scattering volume ( 5 );
• b) the radiation scattered perpendicular to the particle flow is deflected in the direction or approximately in the direction of the axis of rotation ( 17 ) via a reflecting element ( 6 ) which rotates around the scattering volume ( 5 ) and the particle flow;
• c) the angular range in which the scattered light is deflected at every angle of rotation is limited by the width of the rotating reflecting element ( 6 ) or a co-rotating aperture ( 7 ) in front of it; d) the deflected scattered light is imaged onto the optical detection system ( 11 ) via a further mirror ( 9 );
• e) the detection system ( 11 ) is in a fixed position;
• f) the scattered radiation is measured continuously or quasi-continuously in the angular range from 0 ° to 360 °, with the exception of the angular ranges at which the rotating reflecting element ( 6 ) passes through the light beam ( 19 , 20 , 21 ) of the light source;
• g) filters matched to the modulated light are used to evaluate the detector signal:
• h) the scattering intensity is normalized to the intensity at a fixed angle, preferably between 80 ° and 100 ° (260 ° and 280 °).

2. The method and device according to claim 1, characterized in that an electrically modulated laser or a light-emitting diode as the light source is used. 3. The method and device according to claim 1, characterized in that as light sources, two electrically modulatable ones arranged close to each other Lasers are used and the steel of a laser is horizontal and the beam of the other laser is vertically polarized.   4. The method and device according to claim 1, characterized in that in the beam path of the scattered light in a half-plane (for example in Angular range from 0 ° to 180 °) a horizontally polarizing element and in the other half-plane (for example in the angular range from 180 ° to 360 °) vertically polarizing element is inserted. 5. The method and device according to claim 1, characterized in that the light of the particles scattered perpendicular to the particle flow over the rotating reflecting element is deflected parallel to the axis of rotation and the scattered light after a further deflection through a second mirror a collection optics is focused on the detector. 6. The method and device according to claim 1, characterized in that the light of the particles scattered perpendicular to the particle flow over the rotating reflecting element is deflected so that the circle that the Scattered light then forms, at a finite distance on the axis of rotation approximates to a point and thus after the redirection a second mirror is used to focus on the detector. 7. Arrangement according to claim 1, 2 and 5 or 6, characterized in that a signal matched to the modulated light signal Scattered light signal evaluation is used. 8. Arrangement according to claim 1, 3, 4 and 5 or 6, characterized in that that two filters matched to the light signal of a laser Scattered light signal evaluation are used and that the Autocorrelation function of a laser light signal to the associated filter becomes maximum and that the cross-correlation function of a laser light signal for the associated filter becomes minimal.