前苏联专利SU1386049A3 Infrared analyser for relative determination of quantities of some substances in sample of food prod

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权利要求

类似技术

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引用文献

法律状态

优先权

专利摘要:
The invention relates to the analysis of materials, in particular the determination of the presence or relative amount in percent of water, protein or oil in food products, mainly in flour. The purpose of the invention is to improve accuracy. A sample of the product is placed in
公开号:SU1386049A3
申请号:SU823412841
申请日:1982-03-15
公开日:1988-03-30
发明作者:Пертен Питер
申请人:Питер Пертен (SE)；
IPC主号:

专利说明:

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nar-i 26 holder (brother, IRN including (no source I) of light) the disk 15 of the replaceable light filter rotates to a position in which one of its filters located along the perimeter of the disk 15 blocks the path of the beam. The electromagnet 21 removes the reference unit 4 from the outlet 7 of the spherical chamber (CC) 5. At the same time, monochromatic collimated light falls on the sample.
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The light reflected by o5pa: ni.iM gets inside the CC 5. The riocjie is scattered by the matte gold-plated wall of the CC 5. Light enters the photocells 8. The electrical photo signal is amplified, filtered, rectified and converted into a digital signal recorded by the microprocessor. At the focal point is a light interrupter, made in the form of a plate 19, which vibrates at a frequency of 100-200 Hz. 1 h.p.f-ly, 5 un
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The invention relates to the analysis of materials, in particular, to determine the presence or relative (percentage) of certain substances, such as water, protein and oil, in food products, mainly in flour.
The aim of the invention is to improve the accuracy.
Figure 1 schematically shows an infrared analyzer; in FIG. 2 a holder, longitudinal section; figure 3 - the holder, in a perspective view; Fig. A is a compactor for a sample of a material to be tested; figure 5 - holder option.
The infrared analyzer comprises a housing 1 with a window 2, a holder 3 for the sample under investigation, a reference unit 4, a spherical hollow chamber 5 with openings 6 and 7, respectively, for entering and exiting a scanning beam, equipped with photo cells 8 and 9 for detecting reflected light, light source 10 located on a common optical axis, a collimator consisting of two two-convex lenses 11 and 12, a condenser lens 13, a block, replaceable light filters, executed with the possibility of rotation around the axis 14, shifted relative to the optical axis of the light source, A disk 15 is provided on the perimeter of which glass plates 16 are fixed with a light transmittance which is different from each other. The disk is driven in an intermittent rotational motion by an electric stepper; 17; the driver 17 performs a full revolution of 5–15 s.
After the block of replaceable light filters, the light is focused by a lens 18. At the focal point there is a light intercept--, a hoist made in the form of a reducible
plate 19, which periodically blocks light at a higher frequency than 100 Hz, possibly 200 Hz, so that electric
the signals generated by the light will have the frequency that is easily amplified. The interrupted light enters through the collimating condenser 20 into a spherical hollow chamber, the outlet of which is blocked periodically by a reference unit making oscillatory movements in its own plane with the help of an electromagnet 21 or
ical or electrical connection
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with the block of replaceable light filters. The reference block is brought into synchronous oscillatory motion with a block of replaceable light filters between the position of the fully blocked light and the position of the completely free window. The spring 22 serves to return the reference unit to the light blocking position in the event of a de-energized electromagnet. The surface of the reference block, facing the inside of the spherical chamber, may be flat or spherical and the radius of the same radius as the radius of the inner part of the spherical chamber. The surface of the reference block and inside} 1n part of the spherical chamber is covered with a corresponding matte posture to be reflective, chemically ci uiiKon, and non-aging. The surface of the staged block may be made from another strong substance than the inner part of a spherical hollow chamber, for example, from polytetrafluoroethylene.
When the reference unit departs, the light falls through the glass window onto sample 23. The window is filled in the analyzer wall 24, which can be removed, for example, unscrewed from the frame (not shown) of the analyzer. The holder for the test sample is a plate 25 with a laser hole 26 for placing the sample of the test product.
rony window. The holder can be fixed on the wall of the analyzer or rigidly (figure 2), or by means of hinges 27, (figure 1 and 3), or using spring locks, clamping means, hooks or using other known means. The holder may be made of ferromagnetic material or contain a ferromagnetic element. When moving, the holder is held pressed to the wall by means of a permanent magnet 28. Relay contact 29 cuts off the current supply to the light source and / or adjusts the current supply to the electromagnet for the stage unit so that the permanent magnet is in the off state those. the holder moves away from the wall, and the reference unit prevents the penetration of external light into the hollow-shaped hollow chamber and the photocells placed in it, since the latter is adversely affected by penetrating light and other light containing ultraviolet rays. The relay contact can also be connected in such a way that when the holder opens, it will also turn off the current supply to the electric jog motor. In addition, the relay contact can also control other means, such as signaling means. The disconnection of the current supply to the light source is also necessary to ensure that the photocells are in the dark and to prevent unnecessary heat generation.
The magnetic operation of the relay contact can be accomplished in various ways, for example, by complete or partial termination of the magnetic circuit of the permanent electromagnet when the holder is closed, so that the relay contact at
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It is activated by the weakening of the magnetic field acting on it. If the permanent electromagnet is mounted on a movable holder, the relay contact can be activated by amplifying a magnetic field acting on it at the moment of contact of the holder with the wall.
The test sample, flour, is introduced directly into the holder groove (Fig. 2) or into the cassette (Fig. 5), which may have a funnel-shaped extension in the upper part. The groove should not contain protrusions and / or cavities that could interfere with the distribution of flour in the groove or its cleaning after use.
Flour in a groove or a cassette. Seal it under a predetermined pressure with sealer 30, consisting of two different sized elements 31 and 32 with guide rods 33, allowing for their flexible connection, and compression springs 34.
Both parts of the sealant may have the same cross-sectional shape as the opening of the holder. After filling the cassette or directly into the holder, insert the seal with the bottom side forward into the hole of the latter and press it into the said hollow until both elements of the seal come into contact with one another. Then the flour in the holder is compacted under pressure determined by the springs in the compressed position. Thus, the pressure and surface characteristics are determined by the flour in contact with the window. These characteristics of pressure and surface are extremely important for reliable measurement, since otherwise different values can be obtained for several samples from the same flour. the accuracy of the analyzer cannot be better than the largest difference between the above different values obtained with the same flour.
In addition, the lower part of the holder groove may have a plane that is bevelled at an angle of 30-60 in the direction of the analyzer wall.
The analyzer works as follows.
In the groove 26 of the holder 3, a test sample of flour is placed, which is compacted under the predetermined pressure by the compactor 30. The flour is in direct contact with the window 2, which is the only glass between the sample and the photo cells 8. When you press the start button, source 10 light, the stepper motor 17 rotates the disk 15 of the block of replaceable light filters in such a position that one of its filters is on the path of the beam, and the electromagnet 21 removes the reference block 4 from the output light hole 7 of the spherical chamber 5, so then monochromatic collimated light hits the sample. The light reflected by the sample falls inside the spherical chamber 5, where it hits the photocells 8 after it has been scattered by the matte gilded wall of the spherical chamber. The photocells then send a corresponding AC signal at a frequency of 200 Hz due to the vibration of the transducer 19. The electrical photo signal is amplified, filtered, emitted, and converted into a digital signal, which is recorded by the microprocessor.
The disk 15 of the replaceable filter unit continues for some time to remain in the same position, the current going to the electromagnet 21 is turned off and the spring 22 converts the standard unit 7 to the position in which it blocks light from entering the sample, and reflects its matte gold-plated surface reference light into a spherical hollow chamber 5, where this light diffusively hits the photocells 8, which now send an electrical reference signal, which is also an alternating current signal and is subsequently processed In the same way as the sample signal,
In addition, the analyzer can work in such a way that it receives several signals from the sample under test alternating with the reference signals each time one filter of the replacement filter unit remains in a fixed position before the disk 15 is turned by the stepper motor 17 one step to next filter.
For each sample, the above process is repeated sequentially for each filter. The disk 15 has eight filters, but when changing
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Species samples and analyzes are not required to be measured using all filters.
. Assume that the sample and reference are measured twice for each of the six filters, with the first and second measurements labeled 1 and 2, respectively, indicating the filter number (1-6 for six filters). The letter P stands for a sample signal, R is a reference signal.
A microprocessor associated with an infrared analyzer counts
K, K, logb-i- | -, to, X “g
X + Clo§5 --- 5 - RP + P "
J. P 5
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Where. Kg, ..., Kg are constant coefficients determined by the least squares method (for example, P is the first (1) measurement using the second (2) filter), the resulting value is the relative protein content of the flour, if the sample is flour, irradiated sequentially with infrared light of different wavelengths, determined by the six filters used and appropriately selected for this protein analysis.
This infrared analyzer provides high measurement accuracy. Despite the fact that the non-compensated temperature drift significantly affects the accuracy of the measuring devices, in this analyzer the temperature drift is compensated for by processing a change in the signal of the reference unit in a computer so that the corresponding compensating change in the sample signal is achieved by adjusting the gain depending on changes in the signal reference. If necessary, the analyzer can be made insensitive to changes in luminous intensity in the light source 10. If the temperature drift is compensated in the manner described above, it is easy to avoid when changing the analyzer the effects of temperature changes and luminous intensity on the electrical signal of the standard.
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On fpg. S shows a card holder. sample | 1l (jifj3f) naHHH for individual samples of flour, as on fng.1-5. The Pattern Holder is designed in such a way that et o is funnel-shaped at the top and parts of the plate in part of the plate are moved like cassettes in a projector or camera for photographing on glass plates.
The proposed analyzer provides greater accuracy in the control of flour and food products of a similar consistency, which are analyzed for relative content of protein and / or water.

权利要求:
Claims (2)
[1]
1. Infrared analyzer for relative determination of quantities of certain substances in a food sample, mainly in flour, comprising a housing with a window, a holder for a test sample, a reference unit, a spherical hollow chamber with openings for entry and exit of a scanning beam, equipped with photovoltaic cells to register the reflected light, and located on a common optical axis of the light source.
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collimator and interchangeable filter unit, which is designed to improve accuracy, it is equipped with a light interceptor located behind the interchangeable filter unit at the focal point, while the reference block is located on the optical axis of the light source between window for the sample and a hole for the exit of the scanning beam with the possibility of overlapping the latter and is a plate, shape and size similar to the shape and dimensions of the window and hole, and the block of replaceable light filters is rotatable District axis offset relative to the optical axis of the light source, a disc-shaped perimeter .kotorogo fixed glass plate with excellent nother one of light transmission in E.
[2]
2. The analyzer of claim 1, wherein the holder for the test sample is a plate with a groove for placing the sample, while the holder is fixed to the housing, and the groove is located on the side window.
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类似技术:

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公开号 | 公开日

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引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

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US3224324A|1962-09-27|1965-12-21|Monsanto Co|Method of presentation of compressionable fibrous samples|

US3776642A|1972-08-01|1973-12-04|Dickey John Corp|Grain analysis computer|

US3817628A|1972-08-17|1974-06-18|Hoffmann La Roche|Reflectometer for on-line analysis of granular powders|

US4040747A|1972-08-24|1977-08-09|Neotec Corporation|Optical analyzer for agricultural products|

US4082464A|1976-10-07|1978-04-04|Neotec Corporation|Optical analysis system having rotating filters|

US4236076A|1979-02-26|1980-11-25|Technicon Instruments Corporation|Infrared analyzer|

DE3002559C2|1980-01-25|1983-09-22|Vladimir Dr.-Ing. 5100 Aachen Blazek|Measuring head for measuring the radiant power and the radiant energy of lasers|

US4404642A|1981-05-15|1983-09-13|Trebor Industries, Inc.|Apparatus for near infrared quantitative analysis with temperature variation correction|SE454387B|1983-07-04|1988-04-25|Peter Perten|DEVICE FOR AN INFRARODE ANALYZER FOR RELATIVE QUANTITY DETERMINATION OF A CERTAIN OR CERTAIN SUBSTANCE IN A POWDER-MATERIAL MATERIAL|

GB2150917B|1983-12-07|1986-08-28|Ranks Hovis Mcdougall Plc|Sampling and testing particulate material|

US4742228A|1984-04-19|1988-05-03|Gebruder Buhler Ag|Infrared measuring apparatus and process for the continuous quantitative determination of individual components of flour or other groundable food products|

JPH0149890B2|1986-03-20|1989-10-26|Satake Eng Co Ltd|

US5448069A|1991-04-23|1995-09-05|Buhler Ag Maschinenfabrik|Infrared measurement of constituents of particulate foodstuffs|

SE468334B|1991-04-23|1992-12-14|Peter Perten|SETTING AND DEVICE FOR INFRASTRUCTURE ANALYSIS, SPECIFICALLY REGARDING FOOD|

DE69312894T2|1992-12-29|1998-02-12|Philips Electronics Nv|Pyrometer with emission meter|

JP3328045B2|1994-02-08|2002-09-24|日清製粉株式会社|Powder sample preparation device|

US5597237A|1995-05-30|1997-01-28|Quantum Logic Corp|Apparatus for measuring the emissivity of a semiconductor wafer|

FR2737573B1|1995-07-31|1997-09-26|Alliance Instr Sa|METHOD FOR INFRARED ANALYSIS OF A SAMPLE AND DEVICE FOR CARRYING OUT THE METHOD|

DE19714115C2|1997-04-05|1999-12-23|Bran & Luebbe|Device for the optical determination of contents of a free-flowing good|

AU9768098A|1997-10-22|1999-05-10|Ashton Group Limited|Integrated sampling system|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

SE8101655A|SE458724B|1981-03-16|1981-03-16|INFRARED ANALYST ANALYZER MAKES RELATIVE QUANTITY DETERMINATION OF CERTAIN OR CERTAIN SUBSTANCES IN A SAMPLE, SPECIFIC SIGN IN FOOD SUCH AS MILK|

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