RU2687992C1 - Infrared and millimeter radiation imaging device - Google Patents

Abstract

FIELD: measuring equipment.SUBSTANCE: invention relates to measurement equipment and refers to infrared and millimeter radiation imaging device. Device includes a hollow housing with a support frame in the form of two dielectric rings, which has two openings for detecting radiation on opposite sides of the housing. Housing is fixed on holder with post, between dielectric rings there is dielectric substrate made of mica. Dielectric substrate is coated with film absorber of nichrome alloy, and on other side of substrate there is a film structure of thermochromic material, made in form of two versions: layer from Al-VOor layer of black dye – cholesteric liquid crystal composition (CLC). Device has cover made with possibility of opening to provide substitution of substrates.EFFECT: disclosed is infrared and millimeter radiation imaging device.6 cl, 8 dwg, 3 tbl

Description

The invention relates to the technique of radio measurements, in particular for visualization of continuous and pulsed infrared (IR) radiation in the range of 0.4-16.67 μm and millimeter radiation at wavelengths of 2 and 3 mm.

Visualization devices are used to check the efficiency of radiation sources, as well as to determine the size, configuration and average radiation power in the millimeter wavelength range. The development of visualization devices capable of operating in the laboratory, workshop, field tests of radiation sources continues to be relevant.

A thermochromic film is known that represents an emulsion of cholesterol derivatives in a colloidal solution of black dye polyvinyl alcohol (carbon black). (Adamchik, A. Liquid crystals: translation from Polish / A. Adamchik, Z. Strugalsky; ed. By IG Chistyakov M .: Soviet. Radio, 1979. 160 p.). Different mixtures of cholesteric liquid crystals correspond to certain temperature ranges, in which there is a complete change in color - from red to blue.

Cholesteric liquid crystals (CLC) are used to visualize infrared radiation in night vision devices, as well as to visualize the microwave field in waveguides and microwaves in the air.

Disadvantages of CLC: mandatory use of a black substrate; low radiation strength of films; sensitivity to ultraviolet radiation; during prolonged exposure or during storage, there is a shift in the temperature range of color change by ± 1-2 ° C.

A two-dimensional THz-IR converter is known, which is a multi-layer structure consisting of a dielectric substrate coated with a frequency-selective surface (CHIP). On the other side of the substrate is applied a continuous layer with metallic conductivity, coated with an emission layer. The radiation is absorbed by a resonant absorber, the heating of which leads to an increase in the intensity of the emission of the emission layer (Pat. 2447574 RF, IPC H03D 7/00 Converter of terahertz radiation / S.A. Kuznetsov, [and others]; statement. 16.11.2010, publ. 10.04 .2012. Bull. №10).

Disadvantages: the complex structure of metallized microstructures limits the size of the THz-IR converter; use of unique IR cameras; ensuring the required sensitivity of the THz-IR converter is achieved by focusing the THz optics, THz lens.

A two-dimensional THz-IR converter is known, which is a matrix with nanoparticles of metal or alloy embedded in it with a partially filled peak of the density of electronic states at the Fermi level (US Pat. No. 2511070 of the Russian Federation IPC G01J 1/02, G02F 1/00, В82В 1/00 Devices for visualization of sources of terahertz radiation / AK Kaveev [et al.], Patentee: TIDEX LLC; announced October 10, 2012, published on April 10, 2014, Byul. No. 10. -17). The nanoparticles heated by THz radiation convert the energy of THz quanta into heat, and the two-dimensional picture formed by the heated nanoparticles of the converter is visualized by an IR camera.

Disadvantages: the use of IR cameras with an equivalent noise temperature difference of 100 µK; the use of labor-intensive manufacturing techniques for metamaterials with given nanoparticle sizes and their bulk concentration.

The closest to the proposed invention is (RF. Pat. RF 2638381 IPC G 01 J 5/20 Device for visualization of infrared and terahertz radiation / AS Oleinik, MA Medvedev, the date of the announcement. 07/20/2016, date publ. 13.12.2017 , Bull. No. 35). The device contains a flat case with a frame in the form of two dielectric rings and having two windows for recording radiation, while the flat case is fixed on a holder with a stand, between the dielectric rings is placed a THz-IR converter, which is a dielectric substrate with a deposited two-layer film structure Al-VO _x , which is surrounded by a circular gap film heater, on the opposite side of the substrate under the film structure Al-VO _x , is a grid of aluminum, no more than 100 thick nm, with square holes, and the length of the side of the grid is directly proportional to the wavelength of terahertz radiation propagating in a dielectric substrate, on the free part of whose surface there is a thermal sensor.

Disadvantages of the device: precision manufacturing technology of a two-dimensional grid of aluminum.

The technical problem of the present invention is the need to create a device that provides visualization of the distribution of radiation power over the beam cross section in the wavelength range from IR to millimeter, capable of operating under production practice conditions.

The invention is characterized by the fact that in the imaging device infrared and millimeter radiation, containing a hollow body with two windows, one of which is mounted on the end of the body, and another window in the lid, inside the body is a supporting frame in the form of two dielectric rings, between the rings is placed dielectric a substrate of mica grade ST-1, coated with a nichrome (X20H80) alloy absorber film, 17-23 nm thick, on the other side of the substrate there is a film structure made of thermochromic material, we play It is available in two versions: a layer of Al-VO _x or a layer of black dye and HLC; the lid is openable to allow replacement of substrates with a film absorber and the indicated versions of the thermochromic layer in the support frame.

In addition, the claimed device, which, along with the above-described signs, the thickness of the dielectric substrate h should correspond to the ratio λ / h = 50-75, where λ = 2; 3 mm - working wavelengths of millimeter radiation. In addition, a device is also claimed in which aluminum film electrodes are applied on opposite sides of the thermochromic layer. In addition, a device is also claimed in which the surface of the window located in front of the thermochromic material is covered with a two-dimensional metric grid with square holes. In addition, a device is also claimed in which the two-dimensional thermochromic structure of Al-VO _{x is} made in the form of square cells, 0.2 × 0.2 mm in size, separated by gaps of 30 μm in width.

The technical result is the ability to visualize large beams of infrared and millimeter radiation of low and medium intensity in industrial practice due to the use of interchangeable screens as part of a universal body, the screens are made on the basis of metal-dielectric metal-dielectric-thermochromic film layers, differing in the material of the thermochromic layer.

The technical result is based on the implementation as a visualizer IR and millimeter radiation metal-dielectric structure (metal-dielectric-thermochromic layer). A film absorber from a metal or alloy, which has a partially filled peak of the density of electron states at the Fermi level, absorbs radiation at wavelengths of 2 and 3 mm at certain absorber thicknesses due to the plasmon resonance of free electrons and is heated. IR radiation is directly absorbed by the thermochromic layer, causing it to heat. The choice of thermochromic layer based on film structures: Al-VO _x or HLC - black dye, have a certain temperature range of color change, which determines the sensitivity of the visualizer. The use of mica substrates, satisfying the ratio of the wavelength λ of the millimeter range to the substrate thickness h (λ / h≥1 order) provides the optimal performance of the visualizer.

The deposition of aluminum film electrodes on the surface of the thermochromic layer Al-VO _x provides the possibility of its temperature control.

The application of a metric two-dimensional grid on the window in front of the thermochromic layer provides an express determination of the size of the radiation beam.

Performing a thermochromic layer in the form of cells (pixels) 0.2 × 0.2 mm in size, separated by a constant gap of 30 μm wide, on the surface of the dielectric substrate limits the spreading of the color spot image when exposed to constant radiation and increases the speed of the visualizer.

The present invention is illustrated using FIG. 1-8: in FIG. 1 (a, b) shows the structure of the device: a - general view; b - longitudinal section; in FIG. 2 (a, b) shows the structure of metal-dielectric structures on a mica substrate with various materials of the thermochromic layer; in FIG. 3 (a, b, c) shows the graphs of the transmittance, reflection, and absorption of the structures: a - VO _x -Al-mica when irradiated from the VO _x side in the frequency range 170-260 GHz; b - CLC-soot, when irradiated from the side of the CLC layer in the frequency range 170-260 GHz; in - absorption of the structure of the CLC-soot in the wavelength range of 10,000-600 cm ^-1 ; in FIG. 4 shows the graphs of the transmittance of the reflection and absorption of the film structure of the nichrome mica alloy, the thickness of the alloy layer of nichrome 17-23 nm in the frequency range 170-260 GHz; in FIG. 5 shows the hysteresis dependence of the brightness contrast on the temperature of the Al-VO _x medium, with thicknesses of film layers of 100 nm and 60 nm, respectively, and the required specific temperature of thermostating; in FIG. 6 shows the dependence of the color of CLC on temperature; in FIG. 7 shows a setup for measuring the average power of millimeter radiation; in FIG. 8 (a, b, c, d) shows photographs of visualization screens under the action of radiation at wavelengths of 3 mm and 2 mm.

Positions 1-20 denote: 1 - a hollow body, 2 - a lid, 3 - transparent windows, 4-support frame, 5 - a dielectric substrate, 6 - a film absorber, 7 - a thermochromic layer based on Al-VO _x , 8 - a holder, 9 - stand, 10 - metric two-dimensional grid, 11 - thermochromic layer based on CLC-soot, 12 - recorded infrared radiation, 13 - recorded millimeter radiation, 14 - power supply, 15-magnetron, 16 - waveguide microwave path, 17 - visualizer , 18 - film calorimeter, 19 - HF-wattmeter, 20 - power meter.

The inventive device comprises a predominantly cylindrical hollow body 1, with a lid 2, the body and the lid have windows 3 that are transparent to visible and recorded radiation. One side of housing 1 serves to receive millimeter radiation, and the other to visualize changes in the color of the thermochromic layer and receive IR radiation. In the housing 1 between the windows 3 there is a support frame 4 consisting of two dielectric rings, with a dielectric (mica) substrate 5 located between them. On one side, the substrate 5 is covered with a nichrome (X20H80) film metal absorber, 17-23 nm thick, On the other side of the substrate 5 there is a thermochromic layer 7 based on the Al-VO _x film structure or a thermochromic layer consisting of a black dye and a CLC. The housing 1 is fixed on the holder 8 with the stand 9. In the housing 1 in front of the window 3 is placed a two-dimensional metric grid 10.

FIG. 1a shows a general view of the design of the device for visualization of infrared and millimeter radiation.

FIG. 1 b shows a longitudinal section of the design of the device for visualization of infrared and millimeter radiation.

The device contains mica substrates 5 of the ST-1 grade, on which film structures are applied: nichrome-mica-Al-VO _x or nichrome-mica-carbon black. Thermochromic layers based on Al-VO _x 7 and HLC-carbon black 11 function as a screen on which a color image of the projection of the radiation source is formed. The presence in front of the thermochromic layer of a two-dimensional metric grid 10 on the window 3 of the device case allows rapid assessment of the geometric dimensions of the color image (spots).

The device works as follows: millimeter radiation 13, passing through the transparent window 3, falls on the film absorber 6 of nichrome alloy, 17-23 nm thick. At wavelengths of 3 mm and 2 mm, the absorption is 15% and 25%, respectively. The absorbed radiation heats the substrate and the thermochromic layer, after reaching a certain temperature, an image appears at the place of heating. IR radiation 12, passing through the window 3, is directly detected by the thermochromic layer.

Thermochromic layers based on CLC and a layer of a mixture of oxide phases VO _x changes its color when heated, respectively, by 0.5-1 ° C and 32 ° C relative to the initial temperature. Thus, using two variants of thermochromic structures, different values of the energy sensitivity of the device are achieved.

Using the thermostating mode of the Al-VO _x structure, by passing a current through it, it is possible to drastically reduce the heating temperature causing its color to change. Thermostating provides the internal memory mode (saving the image for an unlimited time).

The radiation resistance of film structures based on HLC-soot and VO _x -Al is maintained when they are heated, respectively, at 50 and 200 ° C.

FIG. 2a, the first version of the metal-dielectric structure of the nichrome-mica-Al-VO _x (film absorber-mica-thermochromic layer) is presented. The mica substrate 5 of the ST-1 grade is coated with a nichrome (X20H80) 6 alloy film absorber, 17-23 nm thick, on the opposite side there is a thermochromic layer 7 based on the Al-VO _x film structure with layer thicknesses of 100 nm and 60 nm, respectively.

FIG. 2 b shows the second variant of the metal-dielectric structure nichrome-mica-soot-CLC (film absorber-mica-thermochromic layer), made on the mica substrate 5. The mica substrate 5 of the ST-1 brand is covered with a film absorber from the nichrome alloy (X20H80) 6, thickness 17 -23 nm, on the other side of the substrate is a thermochromic layer 11 based on black dye (carbon black) and a mixture of CLC in vinyl alcohol.

IR radiation 12 is directly absorbed by the thermochromic layer, and millimeter radiation 13 is absorbed by the metal film absorber. The absorption of these radiations causes the thermochromic layer to heat up and change its color when the phase transition temperature is reached. The registration of the incident radiation on the surface of the screen of the visualizer coated with a thermochromic layer occurs visually by a change in its color at the location of the detected radiation. Production of VO _x films was carried out on the basis of the work (US Pat. RF №2623573 IPC С23С 14/24, С23С 14/08, С23С 14/58, Н01С 17/10 A method of manufacturing a film material based on a mixture of phases VO _x / AS Oleinik ; Publ. 27.06.2017. Bull. No. 18).

In CLC, there is a thermal hysteresis of the wavelength of selectively reflected light. The presence of hysteresis leads to the fact that the same wavelength of selectively reflected light appears when heated at one temperature, and when cooled - at another. The magnitude of this deviation depends on the nature of the substance and the amplitude of the temperature change. The temperature deviation corresponding to one wavelength is due to the percentage composition of the mixture (Adamchik, A. Liquid crystals: trans. From Polish. / A. Adamchik, Z. Strugalsky; ed. By IG Chistyakov M .: Soviet Radio, 1979. 160 p.).

Taking into account the identified needs, thermotropic compositions have been developed and are produced, giving color transitions within the temperature range: 23-28, 28-33 31-34, 31-36, 35-38, 36-39, 36-41 ° C. Characteristics of the CLC compositions are shown in table 1.

The most convenient way to obtain liquid crystal films for thermo-optical purposes, for example, for preparing heat-sensitive screens, is aerosol spraying of a solution in an appropriate solvent. Spraying makes it possible to obtain a thin and smooth layer and, most importantly, storing the liquid crystal mixture in solution eliminates the danger of a slow, spontaneous separation of the components of the mixture. In addition, for the manufacture of liquid crystal films, the method of centrifugation can be used, providing more uniform and thin films. First, a black dye is applied to the smooth polished surface of the mica substrate, after hardening of the dye, an emulsion of cholesterol derivatives in a colloidal solution of polyvinyl alcohol is applied (Oleinik AS. Methods for controlling infrared radiation: monograph / AS Oleinik. - Saratov: Saratov. State techn. University, 2014. - 164 p.).

FIG. 3a shows the graphs of transmittance, reflection, and absorption of the VO _x -Al-mica structure when irradiated from the VO _x side.

FIG. 3 b shows the graphs of transmittance, reflection, absorption structure of the polyvinyl film - CLC, when irradiated from the side of the CLC layer in the range of 170-260 GHz.

FIG. 3c shows the absorption graph of the structure of a CLC – carbon black –vinyl film upon irradiation from the side of the CLC layer in the wavelength range of 10,000–600 cm ^–1 . The study of the absorption of the film on the basis of CLC in the range of 10,000-600 cm ^-1 was carried out using a FT-801 spectrometer interfaced with a laptop, in the Zair 3 program.

FIG. 4 shows the graphs of the transmittance, reflection and absorption coefficients of the nichrome layer in the range of 170-260 GHz.

Measurements of transmittance, reflection and absorption coefficients of metamaterials in the frequency range of 170-260 GHz were carried out using a ZVA-40 vector electrical analyzer from Rohde & Schwarz.

A film made of an alloy Nichrome X20H80 (20% Cr, 80% Ni) was used as a meta-absorber. A nichrome alloy film containing metals with a partially filled peak of the density of electron states at the Fermi level converts millimeter radiation energy into heat. The process of applying thin layers of nichrome is carried out by thermal evaporation and condensation in a vacuum. Overheating of the structure relative to the temperature of temperature control provides a visual gradation of the color image, which characterizes the presence of controlled radiation. Erasing the image is provided by the termination of the radiation source.

FIG. 5 shows the dependence of the brightness contrast of the Al-VO _x medium, with thicknesses of layers of 100 nm and 60 nm, respectively, on temperature. The width of the hysteresis loop ΔT is characterized by the temperature difference corresponding to the values of the reflectivity of the structure at the level of the middle of the hysteresis loop during its passage along the forward and backward branches.

Effective change in reflectivity at temperature T _c in memory mode: ΔR (T _c ) = R _m (T _c ) - R _s (T _c ), where R _m (T _c ) and R _s (T _c ) are reflectivity values structures lying respectively on the direct and inverse branches of the temperature hysteresis at a temperature T _c . In the thermostatting mode at the levels of 45 ° С, 54 ° С, to ensure recording in the memory mode, it is required to heat the Al-VO _x structure by 13 ° С and 4 ° С, while the change in the contrast coefficient K of the structure will be 0.2 (the first image brightness). When thermostating at 45 ° C, it is necessary to ensure overheating of the structure by 17 ° C in order to provide two gradations of image brightness. The first and second gradations of the brightness of the image are associated with overheating relative to room temperature by 32 ° C and 40 ° C, respectively. The color transition of the film structure before and after heating is blue-blue, and the saturation of the blue color increases as it heats up. The color transition is clearly visually observed with both indoor and outdoor lighting.

FIG. 6 shows the dependence of the color coloration of CLC on the heating temperature (Shibaev, V.P. Liquid crystals: cholesterics / V.P. Shibaev // Chemistry and Life - XXI century, 2008. -№ 7. -P. 26-30.)

The device contains interchangeable support frames 4, inside which are placed mica substrates 5 of the ST-1 grade, covered with a thermochromic structure: black dye -LCH in vinyl alcohol shell 11, or a layer of a mixture of oxide phases VO _x - aluminum mirror 7, on the other side of the substrate The film absorber is made of nichrome alloy (X20H80) 6. The support frames 4 are placed in a sealed case 1 with a removable lid 2, in which windows 3 that are transparent for visible and recorded radiation are placed. Window 3 located in front of the thermochromic structure is covered film two-dimensional metric mesh 10.

The device works as follows: a thermochromic layer based on the HLC-soot directly absorbs electromagnetic radiation in the wavelength range from IR to millimeter, causing a change in its color coloration. The thermochromic structure of Al-VO _x absorbs radiation in the wavelength range of 0.4–16.67 μm, and the absorption is insignificant at millimeters (not more than 5%). Millimeter radiation is absorbed by the nichrome alloy film (at least 25-40%), transfers heat to the thermochromic structure, the color change of which is perceived visually. The time constant of the screen depends on its heat capacity and the size of the screen surface being irradiated. In the case of the use of CLC, the time constant is determined by the speed of the phase transition and is ≈100 ms, and in the VO _x film the time of the phase transition is ^10–11 s (US Pat. Of the Russian Federation No. 263357373 IPC С23С 14/24, С23С 14/08, С23С 14/58, H01C 17/10 A method of manufacturing a film material based on a mixture of phases VO _x / AS Oleinik // Publ. 27.06.2017. Bull. No. 18).

The color image of the projection of the radiation source (color spot) against the background of a two-dimensional grid makes it possible to visually expressly evaluate its geometrical dimensions.

FIG. 7 shows a setup for measuring the average power of millimeter radiation. The installation contains a power supply 14, which maintains the magnitude of the pulse voltage at the cathode of the magnetron 15, sets the duration of the radiation pulse and changes the pulse duty cycle. The waveguide radiation output is combined with a coupler (HF path) 16. The average power output at the magnetron output was measured using a power level meter 20, consisting of a waveguide calorimetric meter 17 and a wattmeter 18. The millimeter radiation sources were magnetrons with a working wavelength of 3 mm and 2 mm in magnetically shielded version (produced by PJSC "Tantalum", Saratov)

Measurements of the average power of a magnetron source were carried out according to the method ([Electronic resource] Principles of power measurement. Initial guide to measuring power at high and ultra-high frequencies / "Wilcom": wwvv.vilkom.ru).

FIG. 8a shows a photograph of the screen of the visualizer under the action of the radiation of a magnetron with a working wavelength of 3 mm. Exposure time 1 s.

FIG. 8 b shows the dynamics of changes in the color spot on the screen of the visualizer under the action of the radiation of a magnetron with a working wavelength of 2 mm. Exposure time 0.5-5 s.

FIG. 8 c shows a photograph of the screen of the visualizer with a thermochromic layer based on a HLC-carbon black under the action of radiation from a magnetron with a working wavelength of 3 mm. Exposure time 1 s.

FIG. 8 g is a photograph of the screen of the visualizer with a thermochromic layer based on a HLC-carbon black under the action of radiation from a magnetron with a working wavelength of 2 mm. Exposure time 1 s.

Example.

The experimental sample was made of a metal-dielectric structure (metal-dielectric-thermochromic layer) on a CT-1 mica substrate, 60 × 60 × 0.04 mm in size. One side of the substrate is coated with an Al-VO _x film structure, with layer thicknesses of 100 nm and 60 nm, respectively, or a CLC-soot film. On the opposite side of the substrate is a film absorber based on nichrome alloy, 17-23 nm thick. The substrate is placed inside a replaceable support frame consisting of two dielectric rings. The frame is located inside a flat cylindrical body with windows transparent for visible and detectable radiation, made of mica substrates of the ST-1 brand. The body is combined with a handle. Millimeter radiation falls on the surface of the absorber, the observation is conducted from the side of the thermochromic layer. IR radiation falls on the surface of VO _x -Al, on which a color image of the projected radiation is observed. The window in front of the thermochromic structure is covered with a two-dimensional film metric grid. The use of a two-dimensional film absorber based on nichrome alloy, which is applied on mica substrates of the ST-1 brand, ranging in size from 60 × 60 mm to 100 × 100 mm, ensures the registration of large radiation beams. The use of a metal-dielectric-thermochromic layer in the metal-dielectric structure as a thermosensitive CLC layer made it possible to maximize the energy sensitivity of the device when registering continuous radiation in the millimeter wavelength range. The color image of the projection of the radiation source (color spot) against the background of a two-dimensional grid makes it possible to visually expressly evaluate its geometrical dimensions.

The use of replaceable dielectric substrates coated with a metal-dielectric film structure with different variants of the thermochromic layer causes the versatility of the application of the proposed device.

In tab. Figures 2 and 3 show the experimental data on the power density of the radiation of the film structure of the metal-dielectric-thermochromic layer, which provides heating of the thermochromic layer.

In tab. 2, 3 presents the results of measurements of the average power of laser radiation on the working standard of measurements of the average power of laser radiation and the energy of pulsed laser radiation in the wavelength range of 0.3-12 μm (GOST 8.275-2013). Literature:

1. Adamchik, A. Liquid crystals: trans. from polish / A. Adamchik, Z. Strugalsky; by ed. I.G. Chistyakova M .: Sov. Radio, 1979. 160 p.

2. Pat. RF 2447574, IPC H03D 7/00 Converter for terahertz radiation / S.А. Kuznetsov, [et al.]; declare 11/16/2010, publ. 04/10/2012. Bul №10

3. Pat. №2511070 RF IPC G01J 1/02, G02F 1/00, В82В 1/00 Devices for visualization of sources of terahertz radiation / А.К. Caveev [et al.], Patentee: TIDEX LLC; declare 10/01/2012, publ. 04/10/2014, Byul. №10. - 17 s.

4. Pat. RF 2638381 IPC G01J 5/20 Imaging device for infrared and terahertz radiation / A.S. Oleinik, M.A. Medvedev, publ. December 13, 2017, Byul. No. 35

5. Pat. Of the Russian Federation No. 2633573 IPC С23С 14/24, С23С 14/08, С23С 14/58, Н01С 17/10 Method of manufacturing a film material based on a mixture of phases VO _x / А.S. Oleinik // Publ. 06/27/2017. Bul №18

6. [Electronic resource] Principles of power measurement. An initial guide to measuring power at high and ultra-high frequencies / "Vilkom": www.vilkom.ru

Claims (6)

1. Imaging device of infrared and millimeter radiation, containing a hollow body with a supporting frame located in it in the form of two dielectric rings, and having two windows on opposite sides of the body for recording radiation, while the body is fixed on a holder with a stand, a dielectric is placed between the dielectric rings a substrate coated with a thermochromic material structure with a hysteresis dependence of color change on temperature, characterized in that the dielectric substrate of Yuda is coated with a nichrome alloy (X20H80) alloy absorber film, 17-23 nm thick, on the other side of the substrate there is a film structure made of a thermochromic material, performed in two options: a layer of Al-VO _x or a layer of black dye — cholesteric liquid-crystal composition ( CLC), the cover is made with the possibility of opening, to ensure the replacement of substrates with a film absorber and the indicated variants of the thermochromic layer. 2. The device according to p. 1, characterized in that the thickness of the dielectric substrate h must correspond to the ratio

/ h = 50-75, where

= 2; 3 mm - working wavelengths of millimeter radiation. 3. The device according to claim 1, characterized in that the thermochromic material is made on the basis of film structures: black dye - cholesteric liquid-crystal composition or Al-VO _x . 4. The device according to claim 1, characterized in that aluminum film electrodes are applied on opposite sides of the thermochromic layer. 5. The device according to claim 1, characterized in that the surface of the window located in front of the thermochromic material is covered with a two-dimensional metric grid with square holes. 6. The device according to claim 1, characterized in that the two-dimensional thermochromic structure of Al-VO _{x is} made in the form of square cells 0.2 × 0.2 mm in size, separated by gaps of 30 μm in width.

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