RU2561338C1 - Infrared radiation visualisation device - Google Patents

Abstract

FIELD: instrument making.

SUBSTANCE: device comprises an array structure of Golay cells which is closely packed system of the sealed working chambers filled with working gas and which has radiation-absorbing thin metal film. One end face of the array structure is closed by an inlet window for electromagnetic radiation with the transparent antireflecting coating applied on outer side. The second end face of the array structure is closed by a flexible membrane with the thin metallised conducting layer. Transparent conducting coating and thin electrophosphor layer are applied on internal surface of the outlet window. Transparent conducting coating, electrophosphor layer and thin metallised conducting layer of flexible membrane form the electroluminescent condenser. The working chamber is implemented in the form of cylinder with the height equal to its diameter.

EFFECT: increase of frequency of studied radiation, ensuring automatic compensation of changes of ambient temperature and pressure and decrease of weight and dimensional characteristics of the device.

4 cl, 1 dwg

Description

The invention relates to the field of measuring the spatial distribution of electromagnetic radiation far infrared (including terahertz).

The invention can be used in night vision systems, detection of non-shell explosive devices, technical and medical diagnostics.

It is known that radiation receivers are classified into classification:

- a class of photon (quantum) photodetectors in which the photon energy is converted into some primary reaction of the photodetector;

- a class of thermal, in which the photon energy is converted into heat, and the reaction of the photodetector arises as a result of an increase in the temperature of the sensitive element.

The fundamental drawback of photonic photodetectors is the fact that the photon energy is inversely proportional to the radiation wavelength (E = hc / λ where h is the Planck constant; c is the speed of light; λ is the wavelength), which makes their use impossible at wavelengths greater than 20 μm even in the case of cryogenic cooling.

Thermal photodetectors have a constant detecting ability in the range of 1-2000 μm, and in the range of 20-2000 μm are actually the only class of photodetector devices suitable for practical use (see, for example, Kies R.J. et al. Photodetectors visible and IR bands, M. Radio and communications. 1985, p. 64, Fig. 2.22).

In the class of heat receivers, the Golay receiver deserves special attention, surpassing pyroelectric, thermocouple, and thermistor bolometers in operating limits by 5-15 times without cryogenic cooling and being one of the most broadband ones.

The Golay cell is a gas-filled chamber, one end of which is an input window for electromagnetic radiation, and the opposite end is closed by a flexible membrane with a mirror coating on the outside. An absorbing element is placed inside the chamber. The heat-sensitive element of the cell is a gaseous medium, which, when heated, caused by absorption of electromagnetic energy, expands, causing deformation of the flexible membrane, on the outer surface of which a reflective coating is applied. The reading light flux is reflected from the element with varying curvature and enters the position detector.

Depending on the design of the absorbing element, the Golay cells can be selective, in which the radiation absorbs the gas filling the chamber, and, as a result, the spectral sensitivity of the device is determined by the absorption spectrum of the gas filling the chamber. In non-selective devices, radiation is absorbed by thin metal films placed inside the chamber on organic films or chamber walls.

Known technical solution presented in the matrix receiver of terahertz radiation (Patent RU No. 2414688, "Matrix receiver of terahertz radiation", IPC G01J 5/42, publ. 20.03.2011). The receiver has a matrix structure with Golay cells, each of which is a gas-filled chamber, one end of which is an input window for electromagnetic radiation, the opposite end is closed by a flexible membrane with a mirror coating on the outside, and an absorbing element is placed inside the chamber. The absorbing element of the Golay cell is made in the form of an ultrathin (not less than 50 times less than the wavelength of terahertz radiation) resonant absorbing layer containing a high-impedance surface facing the input window of the cell. The matrix contains cells with specified optical characteristics of the absorbing layers due to a given topology of high-impedance surfaces.

A disadvantage of the known technical solution is the use of the classical Goleev scheme for visualizing the spatial distribution of electromagnetic radiation. The classical system for visualizing the geometric surface relief provides for a specialized light source, special optics that form reading and reflected beams.

A known technical solution presented in an infrared detector (US patent No. 7045784 "Method and apparatus for micro-Golay cell infrared detectors", IPC G01J 5/00, publ. May 16, 2006), selected as a prototype. The detector is a sealed assembly of Golay unit cells made on a microchannel plate (MCP) filled with gas, one end of which is an input window for electromagnetic radiation and is closed by a non-deformable membrane, and the opposite end is closed by a flexible membrane with a mirror coating on the outside. The system for visualizing the spatial distribution of electromagnetic radiation in the patent is not detailed.

The disadvantages of the known technical solutions are the lack of a system for automatically compensating for changes in external temperature and pressure, the lack of a technically simple and compact visualization system.

The objective of the invention is to provide a device for visualizing the spatial distribution of infrared radiation in real time.

The problem is solved in that in a device for visualizing infrared radiation, containing a matrix structure of Golei cells, which is a close-packed system of sealed working chambers filled with working gas, inside which there is a radiation-absorbing thin metal film, one end of the matrix structure is closed by an input window for electromagnetic radiation coated with a transparent antireflection coating on the outside, and the second end of the matrix structure is closed by a flexible membrane with a thin metallized conductive layer, a transparent conductive coating is applied to the inner surface of the exit window, then a thin layer of electroluminophore, an electroluminescent capacitor is formed, including a transparent conductive coating, an electroluminophore layer and a thin metallized conductive layer of a flexible membrane, and the working chamber is made in the form of a cylinder with the height of the cylinder, equal to its diameter, and the electroluminescent capacitor is made by feeding alternating current of high frequency, then hot gas is a gas with low heat capacity and high thermal conductivity, further comprising an electroluminescent capacitor is an internal volume filled with a gas, a compensating pressure on the flexible membrane from the working chamber.

The technical effect of the claimed device is to increase the frequency of the investigated radiation, to provide automatic compensation for changes in external temperature and pressure, as well as to significantly reduce the weight and size characteristics of the device, reduce the cost of manufacture and expand the range of devices for this purpose.

In FIG. 1 is a diagram explaining the operation of the inventive device for visualizing infrared radiation, where 1 is a transparent antireflection coating, 2 is an input window, 3 is a sealing adhesive layer, 4 is a metal film, 5 is a matrix structure of Golei cells, 6 is a flexible membrane, 7 - metallized conductive layer, 8 - output window, 9 - transparent conductive coating, 10 - power supply conductors, 11 - electroluminophore layer, 12 - spacer washer, 13 - internal volume, 14 - working chambers.

The inventive device for visualizing infrared radiation operates as follows. The analyzed infrared radiation passes through the input window 2, which is one end of the matrix structure, having a transparent antireflection coating 1 on the outside, and the input window 2 is made of a material that is transparent in the studied wavelength range and cuts off the short-wave part of the spectrum (single-crystal germanium) and penetrates into a matrix structure of 5 Golei cells, which is a close-packed system of working chambers 14. The second end of the matrix structure is closed by a flexible membrane 6 with a thin metallized wire yaschim layer 7.

The system of working chambers 14 is made of photosall using the technology of microchannel plates of electron-optical converters, and the working chamber 14 itself is made in the form of a cylinder with a height equal to its diameter.

In each of the working chambers 14, IR radiation is absorbed by a thin metal film 4, heating it. The heated thin metal film 4 heats the working gas filling the working chamber 14. The working gas is a gas with low heat capacity and high thermal conductivity, for example xenon. The working gas inside each of the working chambers 14 is heated in proportion to the absorbed radiation, and its pressure increases. An increase in pressure in the working chamber leads to deformation of the flexible membrane 6, covered with a thin metallized conductive layer 7. The end surfaces of the matrix structure of the Golei cells 5 are sealed with a sealing adhesive layer 3.

Thus, the spatial distribution of electromagnetic energy is converted into a geometric surface relief of the flexible membrane 6. Additionally, a transparent conductive coating 9 is applied to the inner surface of the exit window 8, then a thin layer of electroluminophore 11, and an electroluminescent capacitor is formed, including a transparent conductive coating 9, an electroluminophore layer 11 and a thin metallized conductive layer 7 of the flexible membrane 6. The second lining of the capacitor is a thin metallized wire the supply layer 7 of the flexible membrane 6. The distance between the conductive layers, namely the metallized conductive layer 7 and the transparent conductive coating 9, is normalized by a spacer 12. The electroluminescent capacitor is made containing a sealed internal volume 13 filled with gas, which compensates for the pressure on the flexible membrane 6 from the side of the working chambers 14. Power supply of the electroluminescent capacitor is carried out by alternating current of increased frequency through the power supply wires 10 of the electroluminescent capacitor.

The classical system for visualizing the geometric surface relief provides for a specialized light source, special optics that form reading and reflected beams. In our case, these elements are completely eliminated and replaced by an electroluminescent capacitor. Thus, the geometric surface relief of a flexible membrane (which is one of the electro-optical capacitor plates) is converted into a two-dimensional distribution of the luminophore glow (deposited on the inner surface of the exit window) in the visible region of the spectrum. This conversion is carried out in real time.

Claims (4)

1. A device for visualizing infrared radiation, containing a matrix structure of Golei cells, which is a close-packed system of sealed working chambers filled with working gas, inside which a thin metal film absorbing radiation is located, one end of the matrix structure is closed by an input window for electromagnetic radiation deposited on an external side with a transparent antireflection coating, and the second end of the matrix structure is closed with a flexible membrane with a thin metallized wire a bare layer, characterized in that in addition to the inner surface of the exit window a transparent conductive coating is applied, then a thin layer of electroluminophore, an electroluminescent capacitor is formed, including a transparent conductive coating, an electroluminophore layer and a thin metallized conductive layer of a flexible membrane, and the working chamber is made in the form cylinder with a cylinder height equal to its diameter. 2. The device for visualizing infrared radiation according to claim 1, characterized in that the electroluminescent capacitor is made of ac alternating current of high frequency. 3. The device for visualizing infrared radiation according to claim 1, characterized in that the working gas is a gas with low heat capacity and high thermal conductivity. 4. The device for visualizing infrared radiation according to claim 1, characterized in that the electroluminescent capacitor is made containing an internal volume filled with gas, which compensates for the pressure on the flexible membrane from the side of the working chamber.