RU49977U1 - FOURIER SPECTROMETER - Google Patents

Abstract

The utility model of a Fourier spectrometer relates to measuring equipment, in particular to spectral instrumentation, and can be used in the manufacture and use of Fourier spectrometers.

The technical task of the utility model is the miniaturization of the Fourier spectrometer, i.e. a significant reduction in size and weight (mass), expanding the possibilities of use and increasing the accuracy of interferometric measurements.

The specified technical problem is achieved in that the FOURIER SPECTROMETER contains a housing, a beam splitter, a compensator, reflectors, and differs from the prototype in that a parallelogram device is located in the housing, and a beam splitter, a compensator, reflectors are located inside the parallelogram device, and one of the reflectors is mounted on the carriage parallelogram device.

The Fourier spectrometer is designed to obtain a spectrum or spectra of radiation by recording the interferogram of the investigated radiation and by its Fourier transform calculating the spectrum or spectra.

When using the utility model, the following technical results will be achieved: reduction in size and weight; the ability to use Fourier spectrometers in portable, field and flight spectrum analyzers because of the small size; the ability to change the signal intensity in the reference channel depending on the optical path difference, thereby providing more accurate registration of the optical path difference in the interferometer; improving the accuracy of interferometric measurements when working at high temperatures.

Description

The technical field to which the utility model belongs. The utility model relates to measuring technique, in particular, to spectral instrument engineering and can be used in the manufacture and use of Fourier spectrometers.

The level of technology. A well-known analogue is a static Fourier spectrometer for the visible region of the spectrum, which contains an input diaphragm, a collimating lens, a beam splitter, one mirror that is rotated relative to the axis of the light flux by an angle alpha, another mirror, made in the form of a step-by-step set of mirror areas such as the Michelson reflective echelon. The beam splitter and the mirrors form a Michelson interferometer, and the mirrors in the interferometer are fixed motionless (USSR Author's Certificate 1494693, class G 01 J 3/45 with publication date 01/27/1995).

The disadvantages of the spectrometer are large dimensions and weight.

Another analogue is known - an interferometer, which contains angular reflectors located on the arms of the rocker arm. The interferometer beam is made with the ability to rotate relative to the axis of rotation of the beam, therefore the reflectors mounted on the arms of the beam, also have the ability to rotate relative to the axis of rotation of the beam (USSR Author's Certificate 1554559, class G 01 J 9/02 with publication date 04/20/1995 g .).

The disadvantages of the analogue are the large dimensions and weight, as well as the inability to move one of the reflectors at a fixed position of the second reflector.

The third analogue (Author's certificate 789688 for class G 01 J 3/26 with the publication date 23.12.80) describes a Fourier spectrometer in which one of the mirrors is arranged to move along the light flux, and the plane of the mirror

always oriented at an angle of ninety degrees to the axis of the light flux.

The disadvantages of the analogue are also large dimensions and weight.

Other Fourier spectrometers are also known in which one of the mirrors during operation translates along the light flux or rotates relative to the light flux. These are the Copyright certificates of the USSR 1649892, 1492890, 1290842, 1300294, 226197. The disadvantages of these spectrometers are the large dimensions and weight of the spectrometers.

The closest in technical essence to a utility model analogue (prototype) can be a Fourier spectrometer containing a housing and a beam splitter, compensator and reflectors located in the housing (Copyright certificate 508665 in class G 01 B 9/02 with publication date 30.03.76) . Additionally, the interferometer contains a light source, a collimating system, a lens with a photodetector. The beam splitter and compensator are made in the form of a single plate, in which a beam splitter coating is applied on half of one of the surfaces.

The disadvantages of the prototype are as follows:

relatively large dimensions and weight;

the inability to use Fourier spectrometers in portable, field and flight spectrum analyzers due to the large size and weight;

the inability to change the signal intensity in the reference channel;

high measurement error at temperature loads on the spectrometer.

Disclosure of a utility model. The claimed Fourier spectrometer is designed to obtain a spectrum or spectra of radiation by recording the interferogram of the investigated radiation and by its Fourier transform calculating the spectrum or spectra.

The technical task of the utility model is the miniaturization of the Fourier spectrometer, i.e. significant reduction in size and

weight (mass), expanding the possibilities of use and increasing the accuracy of interferometric measurements.

The specified technical problem is achieved in that the FOURIER SPECTROMETER contains a housing, a beam splitter, a compensator, reflectors, and differs from the prototype in that a parallelogram device is located in the housing, and a beam splitter, a compensator, reflectors are located inside the parallelogram device, and one of the reflectors is mounted on the carriage parallelogram device.

When using a utility model, the following technical results will be achieved.

1. The reduction in size and weight compared with known devices without deterioration due to the use of a parallelogram device in the Fourier spectrometer as the moving part of the spectrometer and the space inside the parallelogram device for accommodating the elements of the spectrometer. The authors made a prototype Fourier spectrometer (see photo in figure 3). The weight of an experimental spectrometer with a parallelogram device is more than half the weight of similar spectrometers that perform the same functions and contain similar electric motors for moving a movable mirror and made by both authors and other developers. The volume of the claimed spectrometer is 2-3 times less than the volume of known similar devices.

2. The ability to use Fourier spectrometers in portable, field and flight spectrum analyzers due to their small size. The weight of the claimed spectrometer is 500 g (the weight of the spectrometer with a radiation source, a collimating system, a cuvette compartment, an electronic control and recording system and a laptop-type laptop computer is no more than 6 kg). The dimensions of the claimed spectrometer are not much larger than the dimensions of a portable computer - such as a "laptop."

3. The ability (due to the simultaneous movement along the light stream and in the lateral direction from the light stream) to change the signal intensity in the reference

channel depending on the optical path difference, thereby providing a more accurate registration of the optical path difference in the interferometer. The implementation of the reflective element with areas having different reflective characteristics, will allow you to change the signal intensity in the reference channel depending on the position of the reflector mounted on the movable carriage of the parallelogram device.

4. Improving the accuracy of interferometric measurements when operating at high temperatures and deformation of the spectrometer body. Under conditions of thermal deformations of the spectrometer case under the influence of intense radiation (for example, solar radiation, radiation from a rocket engine jet, or radiation from a blast furnace), the spectrometer needs to be adjusted, at least a change in the relative position of the reflectors and the beam splitter with the compensator. The claimed spectrometer adjustment is possible due to the performance of the reflectors with the ability to move relative to the housing, and therefore relative to the reflector and the beam splitter, which are rigidly fixed to the housing. For analogues and prototype such adjustment is not possible.

In addition, the claimed spectrometer will additionally provide increased measurement performance when using several reflective elements with different reflective characteristics in the reflector or when using a reflective element containing regions with different reflective characteristics. During the movement of the carriage with a reflector, the working area moves along the surface of the reflecting element (or along the surfaces of the reflecting elements). Similar spectrometers require the replacement of a reflector for this operation, which takes time.

In the General case, the reflector and the beam splitter can also be made with the possibility of movement relative to the housing, which will expand the adjusting capabilities of the spectrometer.

The parallelogram device is located in the body of the Fourier spectrometer and contains a base, a carriage, supports and clamping

devices. The supports are pivotally connected to the base and the carriage. As clamping devices, springs or elastic bands (rubber bands) are used.

In the claimed Fourier spectrometer, one of the reflectors is mounted on the carriage of the parallelogram device and is configured to simultaneously move along the light flux and in the lateral direction from the light flux.

Another of the reflectors is mounted on a platform, which, by means of adjusting screws, is fixed on the basis of a parallelogram device. In this case, the reflector is made with the possibility of movement both during the preparation of the spectrometer for operation and during operation of the spectrometer. This will allow, without turning off the spectrometer, to quickly eliminate distortions caused, for example, by temperature deformation.

Each of the reflectors includes a reflector housing and a reflective element mounted in the reflector housing or mounted on the reflector housing. In turn, the casing of one of the reflectors is attached to the casing of the spectrometer, namely, to the movable carriage, and the casing of the other reflector is attached to the movable platform, connected through adjusting screws to the base of the parallelogram mechanism.

The base of the parallelogram mechanism is an element of the spectrometer case, namely its bottom.

In this case, the platform with the reflector is connected to the base by means of one or more adjusting screws (in particular, two, three or four adjusting screws).

The inventive spectrometer reflective element is made in the form of a mirror plate, in particular in the form of a flat mirror.

The claimed Fourier spectrometer is designed in such a way that all reflectors are movable relative to the housing both during preparation for operation of the spectrometer and during operation of the spectrometer. Moreover, the spectrometer is designed to allow the movement of the first reflector with a fixed position of the second reflector or vice versa allows

moving the second reflector at a fixed position of the first reflector. This design feature distinguishes the claimed spectrometer from the prototype.

In the claimed Fourier spectrometer, as in the prototype, the beam splitter and compensator are made in the form of interconnected plates. In this case, the beam splitter and the compensator are fixedly mounted on the spectrometer body by means of the bracket of the beam splitter assembly. The beam splitter and compensator are fixed on the basis of the parallelogram device.

As indicated earlier, one of the reflectors is mounted on the carriage of the parallelogram device. Another of the reflectors is mounted on a platform, which, by means of adjusting screws, is fixed on the basis of a parallelogram device.

Devices for moving the platform and the carriage of the parallelogram device are located in the spectrometer case.

As a device for moving the platform with a reflector using screws, and the screws are made with differential thread.

As a device for moving a carriage with a reflector, an electromagnetic device is used containing permanent magnets and an inductor located between the permanent magnets with the possibility of moving relative to the magnets at a distance of 0.01 mm to 10 mm. Permanent magnets are mounted on the carriage, and an inductor is mounted on a bracket connected to the housing.

In this case, the carriage is made with a hole for the passage of the radiation flux.

Additionally, the Fourier spectrometer contains a lens, photodetectors, connectors for connecting to a computer.

A brief description of the drawings. Figure 1 and figure 2 shows the longitudinal and transverse sections of the Fourier spectrometer. Figure 3 presents a photograph of an experimental Fourier spectrometer developed by the authors with an indication of the main elements. On the

figure 4 presents the kinematic diagram of the Fourier spectrometer with two positions of the parallelogram mechanism.

Implementation of a utility model. The FOURIER SPECTROMETER contains a housing with a base 1 and a cover 35, side walls 30, 31, 32 and 33, a beam splitter 3, a compensator 4, reflectors 6 and 11. A parallelogram device is located in the spectrometer case. A parallelogram device comprises a base 1 (it is also the base of the spectrometer), a carriage 8, supports 10 and pressure devices — springs 9. The carriage and supports are made with holes for the passage of radiation. The supports are pivotally connected to the base 1 and the carriage 8. In the supports, the base and the carriage, recesses for the hinges are made. Supports can be two, four, six, eight. In Fig. 1 they are shown in the form of triangular recesses in which the hinges abut.

The beam splitter 3, the compensator 4, the reflectors 6 and 11 are located inside the parallelogram device, and the reflector 11 is mounted on the parallelogram device - on the carriage 8 with the possibility of simultaneous movement along the light flux (direction 36) and in the lateral direction from the light flux (direction 37) - namely This is how a utility model is implemented in a prototype designed and manufactured by the authors.

In the general case, part of the beam splitter 3, or part of the compensator 4, or parts of the reflectors 6 and / or 11 can be located inside the parallelogram device, and the other part of the beam splitter 3, or other part of the compensator 4, or other parts of the reflectors 6 and 11 can be located outside (behind limits) of a parallelogram device. Given the above, these distinguishing features of the claimed Fourier spectrometer may sound like this: at least part of the beam splitter 3 or the entire beam splitter, at least part of the compensator 4 or the entire compensator, at least part of the reflectors 6 and 11 or the reflectors as a whole are inside a parallelogram device. However, the sign does not contradict this situation: a beam splitter, a compensator, reflectors

located inside the parallelogram device. Therefore, it is in this edition that they are given in the formula.

Reflector 6 is mounted on a platform 5, which is connected to the base through three screws 7. Reflector 6 has the ability to move along the light flux, as well as make angular movements relative to the light flux. To move the platform in a certain way, adjust the screws.

Each of the reflectors contains a reflector housing (Fig. 4 shows a reflector 6 in a housing 38 that is mounted on a platform 5) and a reflective element mounted in the reflector housing. In turn, the reflector housing 11 (shown in FIG. 4 by 39) is attached to the spectrometer housing, namely to the carriage 8. There are two total reflectors.

The base 1 of the parallelogram mechanism is an element of the spectrometer housing, namely its bottom.

The platform 5 with a reflector 6 is connected to the base 1 by means of three adjusting screws.

In the spectrometer, each reflective element is made in the form of a flat mirror.

The beam splitter 3 and the compensator 4 are made in the form of interconnected plates. In this case, the beam splitter and the compensator are fixedly mounted on the spectrometer body by means of the bracket of the beam splitter assembly 2. The bracket of the beam splitter 2 assembly is rigidly fixed on the basis of the parallelogram device 1.

The beam splitter is made in the form of a plate, on one of the surfaces of which a beam splitting coating is applied, which ensures that part of the radiation passes through the coating and reflects part of the radiation from the coating. In practice, the coating is also called translucent.

Devices for moving the platform 5 and the carriage 8 of the parallelogram device are located in the spectrometer case.

As a device for moving the platform 5 with a reflector 6, screws 7 with differential thread are used.

As a device for moving a carriage 8 with a reflector 11, an electromagnetic device is used containing permanent magnets 12 and an inductor 13 located between the permanent magnets with the possibility of moving relative to the magnets up to 10 mm. Permanent magnets are mounted on the carriage 8, and the inductor is mounted on a bracket connected to the housing (not shown in the drawing). A hole is made in the carriage for the passage of radiation.

Additionally, the Fourier spectrometer contains a lens 18, connectors 27, 28 and 29 for connecting to a computer.

The housing contains: a radiometer assembly 15, a position sensor assembly 16, an accelerometer assembly 17. The radiometer 15 comprises a mirror lens 18, a bracket 19 with a two-sided flat mirror 20 inclined to the lens axis at an angle of forty-five degrees, an infrared radiation receiver 21 and a reference radiation receiver 22. The position sensor assembly contains two slotted optocouplers 23, which serve as end sensors, as well as a composite optocoupler 24 with a wide beam of radiation, which serves as a sensor of the current position of the carriage 8, on which the mask 25 is fixed, overlaps ayuschaya when moving carriage radiation fluxes of all three optocouplers.

The claimed Fourier spectrometer works as follows.

The luminous flux from the emitter (the object under study) passes through the inlet window 40 in the side wall 31 of the housing and the hole in the support 10 to the beam splitter 3. Part (or half) of the radiation, reflected from the inner translucent surface of the beam splitter plate 3, passes to the reflector (mirror) 11 reflecting from which and passing through the plates 3 and 4 and through the hole in the carriage 8, it enters the lens of the radiometer 15. Another part (or the other half) of the radiation transmitted through the translucent coating of the plate 3 and the plate 4 is reflected from the reflector (s rkala) 6 and reflected from the beam-splitting coating plate 3 also goes into the lens 15. The two parts of the flux met, interfere (overlap), and

the characteristics of the total radiation flux, which ultimately goes to the receiver 20, depend on the optical path difference between the two branches of the interferometer. The optical path difference is changed by moving one of the reflectors or both reflectors relative to the spectrometer housing, in particular with respect to the beam splitter 3, which is rigidly fixed to the housing.

The reflector 11 is mounted on the carriage of the parallelogram device with the possibility of simultaneous movement along the light flux and in the lateral direction from the light flux. In another way, this movement can be described as follows: the reflector 11 is mounted on the carriage of the parallelogram device with the possibility of simultaneous movement above the base (above the base surface) of the parallelogram device and in the direction toward the base or in the direction from the base of the parallelogram device.

The movement of the carriage is as follows. The coil 13 is supplied with the voltage necessary to uniformly move the carriage relative to the spectrometer body at a given speed to the extreme position, which is recorded using optocouplers 22. When the extreme position is reached, the current through the coil is reversed and the carriage begins to move to the other extreme position. With each such passage of the carriage, the receiver registers a signal (the so-called interferogram), the further Fourier transform of which gives the desired radiation spectrum of the object under study. The readings of the current position sensor 24 and the accelerometer 17 are used to ensure uniform movement of the carriage 8.

The measurement results are transmitted via communication lines through connectors 27, 28 and 29 to the computer.

Reflectors 6 and 11 are arranged to move both during preparation of the spectrometer for operation and during operation of the spectrometer. They can also move in turn, i.e. one reflector moves and the other remains stationary. The operating mode is selected depending on the characteristics of the emission spectra.

Figure 4 shows two possible positions of the reflector 11 and the support 10. The carriage moves in the directions indicated by 34. The angle between the two positions of the support 10 is indicated by 41. The angle between the two positions of the platform 5 relative to the base 1 is indicated by 42.

The movement of the reflector along the light flux and in the lateral direction from the light flux occurs when the movement (or the motion vector) of any point of the reflector can be decomposed into two components: parallel to the light flux and perpendicular to the light flux.

This movement can be given another definition. The movement of the reflector along the light flux and in the lateral direction from the light flux occurs when the movement of any (or each) point of the reflector can be decomposed into two components: parallel to the base of the parallelogram device and perpendicular to the base of the parallelogram device. When the spectrometer is in operation, the position of the light flux is strictly fixed relative to the base of the parallelogram device. The flow may be parallel to the base, and more specifically, parallel to the outer or inner surface of the base, or parallel to the risk applied to the base, or parallel to one of the ribs of the plate from which the base is made. In the general case, the flow can pass at an angle from 0.01 degrees to 10 degrees to the base.

Almost all analogues differ from the claimed spectrometer in that their movable reflector does not perform the above described movement. That is, the reflector or reflectors have a point that does not perform the movement described above. For comparison: the movement of reflectors in an interferometer (Copyright Certificate 1554559) is not movement along the light flux and in the lateral direction from the light flux, since the reflectors have a point - the axis of rotation of the reflectors, which does not move either along the light flux or in the lateral direction from a light stream

Thus, when using the utility model, all the technical results indicated in the “disclosing the utility model” section will be achieved.

A reduction in size and weight will be achieved compared with known devices without compromising performance. The claimed Fourier spectrometer uses a parallelogram device as a moving part of the spectrometer. Inside the parallelogram device (or in the internal space of the parallelogram device between the carriage 8, the base 1 and the supports 10), a beam splitter 3, a compensator 4 and reflectors 6 and 11 are placed, or at least a part of the beam splitter, part of the compensator and part of the reflectors are placed. Parts of these elements may extend beyond the boundaries of the internal space of the parallelogram device.

The base of the parallelogram device is the bottom of the Fourier spectrometer. This layout and structural implementation of the movable mechanism of the spectrometer will significantly reduce the weight and dimensions of the device without compromising performance, which is confirmed by the manufacture, measurement and testing of a prototype.

The reduction in size and weight will make it possible to use Fourier spectrometers in portable, field and flight spectrum analyzers.

Also, when the spectrometer is operating, it is possible (due to simultaneous movement along the light flux and in the lateral direction from the light flux) to change the signal intensity in the reference channel depending on the optical path difference, thereby providing more accurate registration of the optical path difference in the interferometer.

There is an additional opportunity to increase the measurement performance when using several reflective elements with different reflective characteristics in the reflector or when using a reflective element containing areas with different reflective

characteristics. No shutdown is required to replace reflectors.

When operating in extreme conditions, namely when exposed to elevated temperatures on the spectrometer body, increased accuracy of interferometric measurements will be provided. Under conditions of temperature deformations of the spectrometer case, the operator adjusts the spectrometer, for example, by changing the relative position of the reflectors and the beam splitter with a compensator.

The utility model can be successfully applied to control the quality of oil products, drinks, as well as any other liquids or gases.

For example, the analysis of the quality of petroleum products in a Fourier spectrometer is carried out by identifying and establishing the conditionality of petroleum products using infrared radiation. The essence of this identification method is that the absorbance is measured for the analyzed sample at the wavelengths selected in the infrared range. The optical density of standard samples of petroleum products at specified wavelengths in the infrared region of the spectrum, as well as indicators characterizing the conditioning of standard samples of petroleum products, are entered into the computer database. When forming the database, the samples are formed into groups. For the analyzed sample of the oil product sample, the optical density is measured at the same given wavelengths as for standard samples from the database. Next, calculate the numerical parameter characterizing the magnitude of the optical densities of the analyzed sample. The value of the numerical parameter is used to judge whether the analyzed sample belongs to a particular group or brand of oil product. After identification of the sample, its condition is determined. The conditionality is determined by comparing the differentials of the joint densities of the distribution of optical densities of the sample and standard samples belonging to an established group or brand, according to the proposed mathematical formulas (the algorithm is described in RF patent 2075062 in class

G 01 N 21/35 dated 03/10/1997). This method using the claimed Fourier spectrometer was tested by the applicant of this utility model ANO "SIP RIA".

From the above it follows that the claimed Fourier spectrometer can be used in the oil refining, petrochemical industry, as well as in all areas of the economy where oil products are used. In addition, it can be used in the food and chemical industries to control the quality of liquids (chemical solutions, drinks, etc.).

Claims (15)

1. A Fourier spectrometer comprising a housing, a beam splitter, a compensator, reflectors, characterized in that a parallelogram device is located in the housing, and a beam splitter, a compensator, reflectors are located inside the parallelogram device, and one of the reflectors is mounted on the carriage of the parallelogram device. 2. The Fourier spectrometer according to claim 1, characterized in that the parallelogram device further comprises a base, supports and clamping devices. 3. The Fourier spectrometer according to claim 2, characterized in that the supports are pivotally connected to the base and the carriage. 4. The Fourier spectrometer according to claim 2, characterized in that springs are used as clamping devices. 5. The Fourier spectrometer according to claim 2, characterized in that the base is the bottom of the spectrometer housing. 6. The Fourier spectrometer according to claim 2, characterized in that in the supports, base and carriage are made recesses for hinges. 7. The Fourier spectrometer according to claim 2, characterized in that the carriage is made with a hole for the passage of radiation. 8. The Fourier spectrometer according to claim 2, characterized in that the supports are made with holes for the passage of the radiation flux. 9. The Fourier spectrometer according to claim 1, characterized in that each of the reflectors contains a reflector housing and a reflective element mounted in the reflector housing or mounted on the reflector housing. 10. The Fourier spectrometer according to claim 9, characterized in that the reflective element contains two surfaces, and reflective coatings are located on the surfaces. 11. The Fourier spectrometer according to claim 1, characterized in that in the housing there are devices for moving the platform and the carriage of the parallelogram device. 12. The Fourier spectrometer according to claim 11, characterized in that as a device for moving the platform with a reflector using screws, and the screws are made with differential thread. 13. The Fourier spectrometer according to claim 11, characterized in that an electromagnetic device comprising permanent magnets and an inductor located between the permanent magnets with the possibility of movement relative to the magnets is used as a device for moving the carriage with a reflector. 14. The Fourier spectrometer according to item 13, characterized in that the permanent magnets are mounted on the carriage, and the inductor is mounted on a bracket connected to the housing. 15. The Fourier spectrometer according to claim 1, characterized in that it contains a lens, photodetectors, connectors for connecting to a computer.