WO2019039955A1 - Working head of an led mini-spectrometer - Google Patents

Abstract

Proposed is a working head of a light emitting diode mini-spectrometer for determining the chemical composition of a substance under analysis in the form of a solid monolithic or fluent substance or a combination thereof, said working head comprising a housing of the LED mini-spectrometer head, which contains an LED emitter and a broadband photodiode that are mounted on a common circuit board. The LED emitter is designed to be capable of generating radiation in a range of 900-2500 nm and directing said radiation at the substance under analysis. The broadband photodiode is designed to be capable of receiving radiation from the LED emitter after said radiation has interacted with the substance under analysis. The LED emitter contains at least six LED chips mounted on the circuit board such that the LED chips are arranged in a circle around the broadband photodiode. The housing of the LED mini-spectrometer head is configured in the form of a half-sphere such that the housing has a spherical side, the inside surface of which is mirrored, and a flat side, and the broadband photodiode is situated in the focus of the spherical side of the housing of the LED mini-spectrometer head. The circuit board on which the LED chips and the photodiode are mounted is an annular circuit board arranged parallel to the flat side of the housing of the LED mini-spectrometer head. The LED chips are situated on the side of the annular circuit board that faces toward the flat side of the housing of the head, and the broadband photodiode is situated on the opposite side of the annular circuit board. At least four LED chips have emission spectrum maxima at different wavelengths.

Description

 WORKING HEAD OF LED MINISTRY METER

TECHNICAL FIELD TO WHICH A USEFUL MODEL RELATES.

The present utility model generally relates to analyzers of the composition of substances, and in particular, to analyzers for determining the chemical composition of solids, particulate matter, or a combination thereof, operating in the spectral range of 900-2500 nm.

BACKGROUND

 Currently, various analyzers of the composition of substances. However, as a rule, they have large size, long working time, high power consumption and use expensive components.

 The closest analogue of the claimed utility model is a liquid and solid composition analyzer, known from the Eurasian application for invention No. 201600067, containing an optical unit with an LED emitter emitting in the spectral range of 900-2500 nm, and a broadband photodiode receiving radiation from the LED after interaction this radiation with the analyte. The analyzer is capable of determining the chemical composition of the analyte in the form of a solid, a liquid substance, or a mixture of them in a wide spectral range, has small dimensions and low energy consumption.

However, when determining the chemical composition of a solid with this analyzer, the radiation from such a substance cannot always be properly obtained by a photodiode, since in practice the surface of the analyzed solid facing the analyzer can often be characterized by an uneven edge, for example, in the case where the solid is monolithic substance with an uneven surface or a non-monolithic substance composed of many solid parts that provide an uneven surface. Due to this uneven surface, the photodiode may not receive all the information about the solid substance being analyzed, and therefore, the radiation passing after interaction with the analyzed substance may not fully characterize the analyzed substance, i.e. in other words, errors or errors may be introduced into it.

 Thus, the disadvantage of this device is the possibility of introducing errors or errors in the result of analysis of the composition of solids, which does not allow for the analysis of the chemical composition of solid materials with a sufficient degree of accuracy.

DISCLOSURE OF THE ESSENCE OF A USEFUL MODEL

This utility model is aimed at solving this problem that occurs when using known devices, in the form of improving the accuracy of determining the chemical composition of solids, namely the accuracy of determining the chemical composition of solid monolithic or non-monolithic materials, as well as their combinations.

To solve this problem, a working head of an LED mini-spectrometer has been proposed for determining the chemical composition of the analyte, which is a solid monolithic or granular substance or a combination of them, comprising a head housing of an LED mini-spectrometer, in which a LED emitter and a broadband photodiode are mounted on a common board. The LED emitter is configured to generate radiation in the range of 900-2500 nm and direct its radiation to the analyte. The wideband photodiode is configured to receive radiation from the LED emitter after the interaction of this radiation with the analyte. The LED emitter contains at least six LED chips mounted on the specified board in such a way that the LED chips are mounted circumferentially around the broadband photodiode. The head of the LED mini-spectrometer is made in the shape of a hemisphere, so that the specified body has a spherical side, the inner surface of which is made mirror-like, and a flat side, and the broadband photodiode is located in the focus of the spherical side head housing LED mini-spectrometer. The board, on which the LED chips and the photodiode are mounted, is a ring board located parallel to the flat side of the head housing of the LED mini-spectrometer. The LED chips are located on the ring plate on its side facing the indicated flat side of the head housing, and the wideband photodiode is located on the opposite side of the ring board. At least four LED chips have emission spectrum peaks at different wavelengths.

 Achievable technical result of this utility model is to improve the accuracy of determining the chemical composition of the analyte, which is a solid monolithic or granular substance or a combination of both, by performing the body of the proposed working head of the LED mini-spectrometer in the shape of a hemisphere with a spherical side, and the flat side, and in which the broadband photodiode is located in the focus of the indicated spherical side of the building usa.

 Due to the specified configuration of the housing of the proposed working head, the radiation from the LED emitter after its interaction with the analyte can be collected on a broadband photodiode, so that the radiation after interacting with all points of the analyzed solid on its surface facing the LED mini-spectrometer housing is directed on a broadband photodiode. Thus, the possibility of errors and errors in determining the chemical composition of a solid substance is significantly reduced and eliminated, since the analysis takes into account information from essentially all points of the surface of the analyzed solid substance facing the head body. In other words, the location of the photodiode in the focus of the mirror sphere ensures the collection of all the radiation in the working head generated by the LED emitter on the photodiode.

In addition, due to the implementation of the board on which the LED chips and the photodiode are mounted, in the form of a ring board installed parallel to the flat side of the head housing, so that the LED chips located on the ring board on its side facing the specified flat side of the head housing, and the wideband photodiode is located on the opposite side of the ring board, the optimal configuration of the components of the proposed working head is ensured to ensure the direction of radiation from the LED chips to the analyzed substance and further direction of this radiation after it interaction on the photodiode.

 Also, due to the fact that at least four LED chips from at least six LED chips have emission spectrum maxima at different wavelengths, the possibility of high accuracy and speed in determining the chemical composition of the analyte is provided.

 According to one embodiment of the present invention, the annular circuit of the working head has an area made with the possibility of radiation from the LED chips passing through it after the interaction of this radiation with the substance being analyzed. Preferably, the ring board has cutouts that allow radiation from the LED chips to pass through them, and the broadband photodiode is located on the site formed by a portion of the ring board

 According to another embodiment of the present invention, the flat side of the housing of the head of the LED mini-spectrometer is at least partially made of glass that is transparent in the range of 900-2500 nm.

 According to another embodiment of the present invention, the head housing of the LED mini-spectrometer comprises protrusions for mounting in the LED mini-spectrometer.

 According to another implementation variant of the present utility model, a broadband photodiode is characterized by a red border of 2500 nm.

According to another implementation variant of the present utility model, LED chips are made on the basis of heterostructures having a substrate containing GaSb, an active layer located above the substrate, containing a solid solution of GalnAsSb, a restrictive layer located above the active layer for localizing the main carriers, containing a solid solution AIGaAsSb, located above the bounding layer of the contact layer containing GaSb, and the buffer layer containing the solid solution GalnAsSb.

 According to another implementation variant of the present utility model, the buffer layer of the geochemical structures is located between the substrate and the active layer and contains indium less than the active layer.

 According to another embodiment of the present utility model, the broadband photodiode is made on the basis of a heterostructure containing sequentially arranged substrate containing GaSb, an active layer containing GalnAsSb, electrical and optical confinement layers containing AIGaAsSb, and a contact layer containing GaSb.

 Other aspects of the present utility model can be understood from the following description of preferred embodiments and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a side view of the working head of the LED mini-spectrometer according to the first embodiment of the present useful model, which schematically shows the internal components of the working head of the LED mini-spectrometer.

 FIG. 2 shows a bottom view of the operating head of the LED mini-spectrometer shown in FIG. 1, which schematically shows the internal components of the working head of the LED mini-spectrometer.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

USEFUL MODEL

The present description reveals the options and features of the working head of the LED mini-spectrometer for determining the chemical composition of the sample being analyzed in the form of a solid, a granular substance, or a combination of these. It should be noted that the disclosed features of the specified working head of the LED mini-spectrometer in any embodiment may be inherent in different variants of implementation in any combination thereof, unless otherwise specified.

 Under the analyzed sample in the present description of the utility model refers to some of any solid monolithic or granular substances or their combinations, preferably used in agriculture, for example, but not as a limitation, grain, feed, peat, hay, bran, etc., which allows determine the chemical composition of any solid monolithic or bulk solids or combinations thereof. In addition, in the present description, the term "sample" can also be replaced by the term "analyte" and vice versa.

 Under the monolithic substance in the present description of the utility model is meant a substance that is a single or integral array of any substance, the particles of which are strongly connected with each other.

 In the present description, bulk solids are understood as a collection of small particles not adhered and not bonded to each other or partially bonded to each other, for example, such a collection of small particles can also be described as a crumbly or powdered substance. In relation to the present utility model, such a substance may be, for example, seeds of grain crops or seeds of plants of the legume family.

 Under the friable substances in the present description refers to easily crumbling substances, the particles of which are not connected or partially interconnected. With reference to the present utility model, such a substance may be, for example, feed.

 Powdered substances are substances that have the appearance of a powder. In relation to the present utility model, such a substance may be, for example, finely ground bran.

The working head is the main working element of the LED mini-spectrometer for determining the chemical composition of the analyte, which is a small portable device operating in the spectral range of 900-2500 nm based on the methods of optical spectroscopy. The working head 100 of a light-emitting diode mini-spectrometer for determining the chemical composition of an analyzed sample according to the first embodiment of the present invention is illustrated by its side view in FIG. 1 and a bottom view in FIG. 2, which schematically shows the internal components of the working head 100 of a LED mini-spectrometer. The working head 100 includes a head housing of an LED mini-spectrometer, in which a LED emitter is mounted on the board 30, which contains six LED chips 10 (only one LED chip is marked for simplicity in the drawings), and a broadband photodiode 20. The used broadband photodiode 20 has a red border of 2500 nm, but it is possible to use photodiodes with an excellent red border.

 The LED emitter is located in the housing of the head of the LED mini-spectrometer and is configured to emit in the range of 900-2500 nm. The LED emitter is mounted on the board 30 in such a way that its radiation is directed to the analyte in the form of a sample located near the flat side 50 of the housing for the interaction of this radiation with the breakdown, and the broadband photodiode 20 is installed with the possibility of receiving radiation from the LED emitter after interacting radiation with a sample at its sensitive site. The board 30, on which the LED chips 10 and the photodiode 20 are mounted, is an annular board installed parallel to the flat side 50 of the head housing of the LED mini-spectrometer. Six LED chips 10 are installed on said board 30 at equal distance from each other around the circumference around the broadband photodiode 20 installed on the site 25 for the photodiode, which is a section of the board 30. The head of the LED mini-spectrometer is made in the shape of a hemisphere, so that the specified case has a spherical the side 40 and the flat side 50, and the wideband photodiode 20 is located in the focus of the spherical side 40 of the head housing of the LED mini-spectrometer.

The flat side 40 of the head housing of the LED mini-spectrometer is completely or partially made of glass that is transparent in the range of 900-2500 nm (sapphire, quartz, BaF ₂ , CaF ₂ ) to enable transmission radiation from the LED chips 10. The LED chips 10 are located on the annular circuit board 30 on its side facing the flat side 50, and for the operation of the LED mini-spectrometer head near the flat side 50 it is necessary to ensure the presence of a sample. The broadband photodiode 20 is located on the opposite side of the ring board 30. The inner surface of the spherical side 40 of the head housing is mirrored, and the four LED chips of these six LED chips 10 have emission spectrum maxima at different wavelengths. The annular circuit 30 of the working head has an area made with the possibility of passing through it radiation from the LED chips 10 after the interaction of this radiation with the sample, which is formed as a cutout in the annular circuit 30, so that the broadband photodiode 20 is located on the platform 25, which represents a section of the board 30 , which is illustrated in FIG. 2. It can be understood to a person skilled in the art that the indicated area of the ring board 30 can also be transparent or translucent portions that allow radiation from the LED chips to pass through them.

 The working head 100 according to the first embodiment has protrusions 60 on the outer side of the hemispherical body, the shape of which allows the working head to be connected to other components of the LED mini-spectrometer. A special device can be used as an LED mini-spectrometer, and in addition, for example, a mobile device, such as a mobile phone, smartphone, communicator, pocket computer, mobile computer such as a laptop or netbook, or another computing device.

The analyzed sample when determining its chemical composition by the working head is located outside the analyzer near the flat side 50 of the head housing. Thus, the LED chips 10 are located on the annular circuit 30 on its side facing the analyte, and the broadband photodiode 20 is located on the opposite side of the annular circuit 30, which ensures optimal configuration of the components of the proposed working head to ensure the direction of radiation from the LED chips to the analyzed substance and the further direction of this radiation after its interaction on the photodiode.

 Thus, the present utility model provides a technical result in the form of improving the accuracy of determining the chemical composition of the analyte by performing the body of the working head of the LED mini-spectrometer in the form of a hemisphere having a spherical side, the inner surface of which is made mirror and flat side, and in which the broadband photodiode is located the focus of the specified spherical side of the hull. The location of the photodiode in the focus of the mirror sphere ensures the collection of all the radiation generated in the working head by the LED chips to the sensitive area of the photodiode.

 It should be noted that for a specialist it may be obvious to use LED chips of more than six, and use of LED chips that are available, which may have emission spectrum maxima at different wavelengths, more than four.

 For example, in one of the embodiments, the working head of the LED mini-spectrometer contains an LED emitter of 8 LEDs emitting at different wavelengths (1, 3, 1, 45, 1, 6, 1, 7, 1, 95, 2,15, 2, 25 and 2.35 μm), and a broadband photodiode with a red border of 2400 nm with a diameter of a sensitive area of 2 mm.

 In another possible embodiment, the working head of the LED mini-spectrometer contains a LED emitter of 12 LEDs, in which at least 4 LED chips emit at different wavelengths (1, 3, 1, 45, 1, 6, 1, 7 μm), and a broadband photodiode with a red border of 2300 nm with a diameter of a sensitive area of 2 mm.

In another possible embodiment, the working head of the LED mini-spectrometer contains a LED emitter of 24 LEDs, in which at least 8 LED chips emit at different wavelengths (1, 3, 1, 45, 1, 6, 1, 7, 1, 95 , 2.15, 2.25 and 2.35 μm), and a broadband photodiode with a red border of 2400 nm with a diameter of a sensitive area of 2 mm. In another possible embodiment, the working head of the LED mini-spectrometer comprises an LED emitter of 32 LEDs, in which at least 12 LED chips emit at different wavelengths (1, 3, 1, 4, 1, 45, 1, 55, 1, 6, 1, 7, 1, 75, 1, 8, 1, 95, 2.15, 2.25 and 2.35 μm), and a broadband photodiode with a red border of 2500 nm with a sensitive area diameter of 2 mm.

 The increase in the number of LEDs is associated with a decrease in the error of illumination and, therefore, leads to a more qualitative chemical analysis of the composition of the analyte. All the above embodiments of the working head of the LED mini-spectrometer provide improved accuracy in determining the chemical composition of the analyte.

 A mini-spectrometer, in which the proposed working head can be used, can exchange information with a mobile device or computing device in any known manner, including as an example a universal serial bus (USB), RS-232, RS-485, WiFi, Bluetooth or any other suitable compound. Additionally or alternatively, a mini-spectrometer, in which the proposed working head can be used, can have a memory (for example, non-volatile or volatile memory, such as flash memory, RAM, magnetic media, etc.) or can be configured to recording information on another machine-readable medium (for example, optical discs, etc.).

In some embodiments, the LED chips of the LED matrix can be made on the basis of heterostructures disclosed in the same applicant's patent EA 01830 with the title “Heterostructure Based on GalnAsSb Solid Solution, Method of Manufacturing, and LED Based on This Heterostructure”. These heterostructures have a substrate containing GaSb, an active layer containing a GalnAsSb solid solution and located above the substrate, a restrictive layer for localizing the main carriers, containing an AIGaAsSb solid solution and located above the active layer, a contact layer containing GaSb and located above the restrictive layer, and a buffer layer containing a solid solution of GalnAsSb. The buffer layer of the first heterostructure is a low-alloyed pO buffer layer with a composition close to GaSb, due to which the pO-GalnAsSb / n-GalnAsSb reverse-included pn junction provides hole localization in the active region near the heterojunction between the buffer layer and the active layer. In addition, the growth of the pO-GalnAsSb layer, which is structurally perfect with a minimum concentration of impurities and defects, minimizes the effect of defects growing from the substrate into the active region, which leads to a decrease in the deep acceptor levels and, accordingly, the fraction of Shockle-Reid-Hall nonradiative recombination. In addition, due to the fact that the het eros, the culture is grown with a low doping level of the pO buffer layer, i.e. a level close to its own concentration, a significant increase in quantum efficiency is obtained, and the direct operating voltage of such a heterostructure increases slightly, i.e. not several times, as is the case in thyristor-type structures. In the process of growing the buffer layer according to the present utility model, lead is not used as a neutral solvent. In some embodiments, the buffer layer is located between the substrate and the active layer and contains less indium than the active layer.

 In turn, in some embodiments, the photodiode is made on the basis of a heterostructure, the manufacturing technology of which is described in the Eurasian patent Ne 018300 “Heterostructure based on the GalnAsSb solid solution, the method of its manufacture and the LED on the basis of this heterostructure” of the present applicant. The specified heterostructure contains successively located substrate containing GaSb, the active layer containing GalnAsSb, the layers of electrical and optical limitations containing AIGaAsSb, and the contact layer containing GaSb.

When determining the chemical composition of the analyzed sample using the working head of the LED mini-spectrometer according to any of the above options for implementation, first ensure the presence of the analyzed sample near the flat side of the housing of the working head of the LED mini-spectrometer, and then pulses are applied to the LED chips, so that their radiation interacts with a substance that is a component of the sample being analyzed, such as, for example, water, fat, glucose, mineral substances, etc. (partial absorption of radiation occurs, the intensity of which is proportional to the amount of such a substance, which is a component of the sample being analyzed) and is directed towards the broadband photodiode, which receives this radiation and generates the corresponding signals. During the supply of pulses, they are successively fed to individual LED chips with a shift in time. In some embodiments, to determine the chemical composition of the sample being analyzed, the spectrum obtained from the signals generated by the photodiode and containing information on the absorption of light at a given wavelength can be compared with at least one known reference spectrum. In addition, in some embodiments, in addition to determining the chemical composition of the sample to be analyzed, the concentration of substances in the sample being analyzed is determined.

 In some embodiments, the supply of pulses to the LED chips further comprises applying pulses to at least one pair of LED chips, the emission spectrum maxima of which are characterized by adjacent wavelengths, and when applying pulses to at least one pair of LED chips, pulses are simultaneously applied to each LED A chip of a specified pair of LED chips in such a way that each LED chip is switched on with a different power. Preferably, when pulses are applied to the LED chips, the pulses are successively supplied to more than one pair of LED chips with a shift in time.

Thus, the pulsed power LEDs allows for a smooth scanning of the investigated range of 900-2500 nm, since the spectral radiation of the LED chips has the form of a Gaussian curve. By applying power simultaneously to two adjacent wavelength LEDs, it is possible to obtain a total spectrum with a maximum between the maxima of the individual LEDs. By reducing the current in small steps on the first LED chip from one pair and by synchronously increasing the current on the second LED chip from this pair, a fairly smooth maximum shift can be obtained total radiation spectrum. The scanning resolution is determined by the number of LED chips and the width of their spectra.

 This utility model is not limited to specific implementation options disclosed in the description for illustrative purposes, and covers all possible modifications and alternatives included in the scope of this utility model, a certain formula of the utility model.

Claims

FORMULA OF USEFUL MODEL

1. The working head of the LED mini-spectrometer, designed to determine the chemical composition of the analyte, which is a solid monolithic or granular substance or a combination of them, containing

 The body of the head of the LED mini-spectrometer, in which the LED emitter and the broadband photodiode are mounted on a common board,

 moreover, the LED emitter is made with the ability to generate radiation in the range of 900-2500 nm and the direction of its radiation on the analyte,

 the broadband photodiode is configured to receive radiation from the LED emitter after the interaction of this radiation with the analyte,

 the LED emitter contains at least six LED chips mounted on the specified board in such a way that the LED chips are mounted circumferentially around the broadband photodiode,

 characterized in that

 the head of the LED mini-spectrometer is made in the shape of a hemisphere, so that the specified body has a spherical side, the inner surface of which is made mirror-like, and a flat side, and the broadband photodiode is located in the focus of the spherical side of the head housing of the LED mini-spectrometer,

 moreover, the board on which the LED chips and the photodiode are mounted is an annular circuit located parallel to the flat side of the head housing of the LED mini-spectrometer,

 the LED chips are located on the ring board on its side facing the said flat side of the head housing, and the wideband photodiode is located on the opposite side of the ring board,

at the same time, at least four LED chips have emission spectrum maxima at different wavelengths.

2. The working head according to claim 1, in which the annular circuit has an area made with the possibility of passing through it the radiation from the LED chips after the interaction of this radiation with the analyte.

3. The operating head according to claim 2, wherein the ring plate has cutouts that allow radiation from the LED chips to pass through them, the broadband photodiode being located on the platform formed by a part of the ring plate.

4. The working head according to any one of paragraphs. 1-3, in which the flat side of the housing head LED mini-spectrometer is at least partially made of glass, transparent in the range of 900-2500 nm.

5. The working head according to any one of paragraphs. 1-4, in which the head housing of the LED mini-spectrometer contains protrusions for mounting in the LED mini-spectrometer.

6. Working head according to any one of paragraphs. 1-5, in which the broadband photodiode is characterized by a red border of 2500 nm.

7. Working head according to any one of paragraphs. 1 - 6, in which the LED chips are made on the basis of heterostructures having a substrate containing GaSb, an active layer located above the substrate, containing a GalnAsSb solid solution, located above the active layer, a restrictive layer for localizing the main carriers, containing an AIGaAsSb solid solution, located above the restricting layer a contact layer containing GaSb, and a buffer layer containing a solid solution of GalnAsSb.

8. The working head according to claim 7, in which the buffer layer of the heterostructures is located between the substrate and the active layer and contains indium less than the active layer.

9. The working head according to any one of paragraphs. 1 to 8, in which the broadband photodiode is made on the basis of a heterostructure containing successively located substrate containing GaSb, an active layer containing GalnAsSb, electrical and optical limiting layers containing AIGaAsSb, and a contact layer containing GaSb.