RU2108553C1 - Infra-red proximate analyzer - Google Patents

Abstract

FIELD: physics; proximate analysis of agricultural and food products. SUBSTANCE: infra-red proximate analyzer has wider spectrum operating range (& 50-2700 nm). It also has system of turning mirrors provided with electronic control unit and integrating sphere which is additionally fitted with two photoreceivers having thermoelectric coolers. Use of internal wall of sphere with golden coating as standard increases stability and accuracy of 100-per cent reflection measurement considerably. To improve accuracy and thermal stability of photometric characteristics and reproducibility of wave lengths, use is made of three types of materials with linear thermal expansion coefficient close to zero. Common base, parts of interferometer and integrating sphere bodies are made of devitrified glass, beam splitter moving and stationary mirrors of interferometer and mirrors in system of turning mirrors are manufactured of quartz. Fastening parts are made of superinvar. EFFECT: enhanced stability and accuracy of measurements. 2 cl, 2 dwg

Description

 The invention relates to the field of physics, in particular, to the class of spectral devices and can be used for quantitative express analysis of agricultural and food products in the near infrared region of the spectrum, and with appropriate software it will allow to analyze pharmaceutical, chemical and other types of products.

 Foreign infrared express analyzers are known that contain a stabilized radiation source, focusing optics, a monochromator based on a concave holographic diffraction grating, band-pass interference filters, a system of rotary mirrors with a chopper (modulator) for switching measurement channels, integrating a sphere, photodetectors, and a cell for the sample under study ( Brochures of the company "NIR-systems", Spectrophotometer model 4250A, 4250B, 51A, 6250, 5000, 5500, 4500 (USA), Catalog of the company "Alfa / Laval / Bran + Luebbe" Analusentechnik ", InfraAlyzer 500-Systeme, 1993, Germany) .

 The disadvantages of the above devices are: a fixed value of spectral resolution, determined by the aperture and the parameters of the diffraction grating and limiting the number of points in the spectrum, as well as the instability of the photometric characteristics and reproducibility of wavelengths when recording spectra required during quantitative analysis.

 Closest to the technical nature of the present invention is a device for measuring the concentration of sugar (European patent specification N 0317121Bl, Int. Cl .: G 0l N 21/35), containing a Michelson interferometer, consisting of a radiation source, a radiation intensity control unit, a beam splitter, optically coupled movable and fixed mirrors, a scanning mirror scanning drive and an integrating sphere containing a measuring cell with a sample, a standard and a photodetector connected in series with an amplifier, an ADC, and a computer once that latter inputs connected to the outputs of the radiation intensity stabilization unit and the scan drive of the movable mirror.

 The disadvantages of this device are the limited operating range of the spectrum (950-1450 nm), the imperfection of the design of the unit for measuring diffuse reflection (an integrating sphere and a stationary spherical mirror), which allows measuring only liquid samples or solutions, as well as the instability of the calibration reference sample from temperature and other factors , which is used as "clean water".

 The objective of this invention is to provide a thermostable design of an infrared analyzer that allows for the quantitative express analysis of the studied food and agricultural samples in any form (solid, loose, pasty, and liquid) without their destruction.

 As a result of use, the invention improves the accuracy and reproducibility of the analysis, and at the same time ensures its expressity practically without sample preparation of samples in kind (in some cases, grinding is necessary).

The above result is achieved by the fact that the infrared express analyzer is equipped with a common glass base, on which a Michelson interferometer is rigidly fixed, containing a radiation source connected to a radiation intensity stabilization unit and a parabolic mirror with an off-angle of 90 ^° installed along the radiation, band-pass interference filters, a beam splitter, optically coupled movable and stationary mirrors, a scanning mirror drive of a movable mirror, and also foci mounted along the radiation lens, swivel mirror system with electronic control unit. On the same basis, an integrating sphere is made, made of ceramic with an internal gold coating, into which two photodetectors are additionally introduced so that one silicon-based photodetector is located under the measuring cell with a sample for recording diffuse transmission, and the other two (based on lead sulfide ) are located symmetrically with respect to the first photodetector in the lower part of the sphere for recording diffuse reflection and transflection (an analog of the method of double transmission of light into the classical spectrum Oscopy), all photodetectors equipped with thermoelectric coolers and connected in series with an amplifier, ADC and computer.

The system of rotary mirrors is made in such a way that it uses three working surfaces with the possibility of rotation at an angle of 120 ^o in opposite directions with respect to the axis of rotation, which are spatially offset so that the first working surface is a curtain that covers the radiation beam exiting the interferometer, a second working surface is a mirror that directs the radiation beam emerging from the interferometer to the sample at an angle of 90 ^o + 1 and a third working surface is a mirror that directs n choke radiation from the interferometer to the inner wall of the integrating sphere and is displaced along the rotation axis by a distance equal to the difference of the optical path of rays between the wall of the sphere and the surface of the sample to ensure equality of the light beams.

 To achieve the analyzer’s versatility, it expanded the operating range of the spectrum (750-2700 nm) due to the special technology of manufacturing the interferometer beam splitter and improved the design of the unit for measuring diffuse reflection, transmission and transflection, consisting of a system of rotary mirrors equipped with an electronic control unit and a transformed integrating sphere , additionally equipped with two photodetectors with a feasibility study, which allows you to analyze both solid, bulk, liquid and pasty samples. The use of the inner wall of the integrating sphere with a gold coating as a reference will significantly increase its stability and the accuracy of measuring 100% reflection.

 To increase the reproducibility and thermal stability of the photometric characteristics and the reproducibility of wavelengths, three types of materials with close to zero thermal expansion coefficient (linear expansion temperature coefficient) were used in the express analyzer design, namely: the common base, body parts of the interferometer and integrating sphere are made of glass metal, a beam splitter, the movable and fixed mirrors of the interferometer and mirrors of the system of rotary mirrors are made of quartz, and the fasteners are made of superinvar.

 In FIG. 1 - shows the optical scheme of an infrared express analyzer; in FIG. 2 - mutual arrangement of two rotary mirrors and one curtain.

The infrared express analyzer contains a Michelson interferometer 1, consisting of a radiation source 2, a radiation intensity stabilization block 3, a parabolic mirror 4 with an off-angle of 90 ^{° from the} beam splitter 5, a fixed mirror 6 and a moving mirror 7, and a scanning drive for the moving mirror 8, as well as in the course of radiation, band-pass interference filters 9, a focusing lens 10, a system of rotary mirrors 11 connected to an electronic control unit 12 and containing a shutter 13 that overlaps the radiation beam, coming from the interferometer 1, mirror 14, directing the radiation beam to the test sample 19 and mirror 15, directing the radiation beam to the inner wall of the integrating sphere, integrating the sphere 16 with photodetectors 17, thermoelectric coolers 18 and the cell for the studied samples 19, amplifier 20, analog a digital converter 21, a computer 22, and a common ceramic base 23.

 In this case, the computer is connected to the ADC, the radiation intensity stabilization unit, the scanning mirror drive and the electronic control unit.

Infrared express analyzer works as follows. The radiation beam from a stabilized high-intensity radiation source 2 falls on a parabolic mirror 4, which rotates it 90 ^° and directs it to the band-pass interference filters 9. The radiation transmitted through the filters is incident on a beam splitter 5, which divides the radiation beam in half, each of which falls on a stationary 6 and movable 7 mirrors. Reflected from the mirrors, the beams interfere and fall on the focusing lens 10, which directs the total beam to the system of rotary mirrors 11 located in relation to each other with an offset (Δ). Three working surfaces rigidly fixed to each other (13 — the shutter, 14 and 15 — mirrors) alternately direct the radiation beam either to the sample 19 or to the inner wall of the integrating sphere 16. They are depicted by different dashed lines for each moment of measurement. Diffuse radiation reflected from the sample is detected by photodetectors 17, which are connected to thermoelectric coolers 18, which increase their sensitivity (in the case of diffuse reflection from solid or bulk samples and in the case of transflection from pasty samples), and a photodetector 17 (in the case of diffuse transmission from liquid or pasty samples). The signals from the photodetectors are amplified by an amplifier 20 and transferred to an analog-to-digital converter 21, which in a digitized code transmits them to a computer 22. All elements of the optical circuit are rigidly fixed to a ceramic base 23.

The system of rotary mirrors using two mirrors and one curtain, works as follows. In this case, three working surfaces were used, rotating (swinging) at an angle of 120 ^o in opposite directions with respect to the axis of rotation, which are spatially offset so that the first working surface 14 is a mirror directing the radiation beam from the interferometer to the sample under study at an angle of 90 +1 ^o and providing the output of the parasitic mirror component back through the outlet of the integrating sphere; the second working surface 13 is a shutter (dark background), which overlaps the working beam emerging from the interferometer and serves to measure the noise of the device; the third working surface 15 is a mirror directing the radiation beam from the interferometer to the inner wall of the integrating sphere at an angle, ensuring the absence of spurious illumination of photodetectors and the output window of the sample, and it is further offset along the axis by a distance equal to the difference in the optical path of the rays between the wall of the sphere and the surface of the sample (Δ). One turn of 120 ^o to the right and one turn of 120 ^{o to the} left provide one working cycle of measurements.

Claims (2)

1. An infrared express analyzer containing a Michelson interferometer, consisting of a radiation source connected to a radiation intensity stabilization unit, a beam splitter, optically coupled movable and fixed mirrors, a scanning mirror drive and an integrating sphere containing a measuring cell with a sample, a reference and a photodetector, connected in series with an amplifier, analog-to-digital converter (ADC) and a computer, the inputs of the latter being connected to the outputs of the stabilization block radiation and scanning drive of a moving mirror, characterized in that a rotary mirror system and an electronic mirror position control unit connected to it and a computer are introduced into it, the rotary mirror system is made in the form of three working surfaces rigidly fixed to each other with the possibility of rotation through an angle of 120 ^o in opposite directions with respect to the axis of rotation, which are spatially offset so that the first working surface is a shutter that blocks the radiation beam emerging from the interferometer a, the second working surface is a mirror directing the radiation beam from the interferometer to the test sample at an angle of 90 + 1 ^o , and the third working surface is a mirror directing the radiation beam coming from the interferometer to the inner wall of the integrating sphere, and is displaced along the axis of rotation by a distance equal to the difference in the optical path of the rays between the wall of the sphere and the surface of the sample to ensure the equality of light beams, and in the integrating sphere two photodetectors are additionally introduced in this way then one photodetector is installed under the measuring cell with the sample, and the other two are located symmetrically with respect to the first photodetector in the lower part of the sphere, connected in series with the amplifier, ADC and computer, and all three photodetectors are equipped with thermoelectric coolers, while the sphere wall made as a reference of the glass-ceramic with an inner gold plated, and an interferometer installed parabolic mirror vneosevitosti angle 90 ^o, in the course of which there are three band radiation and terferentsionnyh filter with spectral subbands 750 - 1100 nm, 1100 - 1900 nm and 1900 - 2700 nm, and the output of the interferometer is set focusing lens.  2. The device according to claim 1, characterized in that the Michelson interferometer, a system of rotary mirrors with an electronic control unit, an integrating sphere, an amplifier, and an ADC are installed on a common base made of glass, and the housing of the interferometer and integrating sphere is also made of glass, and the beam splitter, movable and fixed mirrors of the interferometer and mirrors of the system of rotary mirrors are made of quartz.

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