RU2662253C1 - Thermal imaging module - Google Patents

Abstract

FIELD: instrument engineering.

SUBSTANCE: invention relates to the field of optoelectronic instrumentation, in particular, to the infrared images into visible ones conversion devices, and can be used as the thermal imaging devices input modules, used in the phased antenna arrays radio-transparent covers monitoring. Device contains lens, in which focal plane an infrared detector is installed, as well as microwave filter made in the form of circular waveguide with inner diameter of at least λ/2, and length of λ. At that, the lens is secured inside the circular waveguide by the nut at a distance of 1 to 100 mm from the waveguide input through the gasket from conductive absorbing material, installed between the lens and the circular waveguide.

EFFECT: invention enables technical result consisting in improvement of the thermal vision image formation reliability and quality.

6 cl, 1 dwg

Description

The invention relates to the field of optoelectronic instrumentation, in particular, to devices for converting infrared images into visible ones, and can be used as input modules of thermal imaging devices used in monitoring radio-transparent shelters (RPU) of phased antenna arrays (PAR).

In radiolucent shelters transmitting headlamps with a high flux density of medium microwave power (tens of kW), heat is generated due to losses in the dielectric materials of their structures. The magnitude of losses depends both on the design and on the operating conditions of the RPU, therefore, both at the stage of creating the RPU PAR and during the operation, the temperature regime of the RPU is monitored. One way to control the heating of RPU structures is to control the temperature of the outer surface using thermal imaging devices.

Thermal imaging devices record the temperature distribution on the outer surface of the entire RPU or on the outer surface of individual sections of the shelter. This allows you to localize the place of heating and in a timely manner to find out the cause of overheating of radiolucent structures both at the inspection stage according to technical specifications and during operation.

To measure the temperature regime, a thermal imaging device must be placed in front of the RPA FAR and, in this case, is exposed to microwave fields. The design of the thermal imaging device should provide its protection from the effects of microwave fields. The microwave power flux density in the aperture of the antenna can be 10-50 kW / m, which makes it necessary to use dielectric materials with low losses in the manufacture of RPUs (tgδ <10 ^-3 ). But, even small losses lead to heating of the dielectric structure. Excessive heating leads to a change in the characteristics of the dielectric, which can cause an additional increase in losses. In connection with the foregoing, a current temperature assessment and monitoring of heating during the operation of the phased array and other objects with powerful transmitting antennas are necessary.

The complexity of the implementation of thermal imaging control lies in the fact that with a high level of microwave power flow, the devices cannot function and often fail. Therefore, when conducting work, it is necessary to protect thermal imaging equipment under the influence of a powerful microwave field. At the same time, microwave protection should not distort or impede visual thermal control, which makes it necessary to develop optical screens that protect equipment at a sufficient level and attenuate the microwave signal to acceptable values.

A technical solution is known [RU 2125222, C1, F41G 1/00, 01/20/1999], containing an armored enclosure of the input optics of a thermal imaging sight, containing an armored cap of the sight with protective glass and an armor cap that is made with an opening corresponding to the field of view of the sight, taking into account the angles pumping in a vertical plane, in front of it there is an additional armor cover with slotted openings and a quick opening drive, while along the perimeter of the hole of the armor cover and outside around the perimeter of the additional armor cover flanges are installed, the width and height of which are equal to the thickness of the corresponding covers, and the additional cover is made thick, providing compensation for the decrease in its strength due to slotted holes.

This technical solution protects the input optics and electronics of the thermal imaging device from mechanical and fire effects, but has a relatively low efficiency of protection against microwave radiation and, when used, a relatively low quality of the formation of the visible image is realized due to distortions introduced by the armor cover.

The closest in technical essence to the proposed one is a thermal imaging module [RU 92973, U1, G02B 23/12, 04/10/2010] containing an infrared lens with a photodetector installed in its focal plane, including a thermal radiation array receiver and a video signal conditioning apparatus, as well as electric defocus compensator, located on the optical axis of the lens in front of the thermal radiation receiver, made in the form of a lens mounted to move along the axis of the lens , an electronic signal processing unit including an electrically connected interface converter, a control device and an image forming and processing device, wherein the first input of the interface converter, which is the first input of the electronic signal processing unit, is connected to the output of the video signal conditioning device, the second output of the interface converter, which is the first the output of the electronic signal processing unit, is connected to the input of the optical displacement lens of the optical compensator, the first you the course of the interface converter is connected to the first input of the image forming and processing device, the second input of the interface converter is connected to the first output of the control device, the first output of the image forming and processing device is the second output of the electronic signal processing unit and serves to connect the video monitor of the application object, the second input of the forming device and image processing is connected to the second output of the control device, the first input of which is the second input of e electronic signal processing unit and is used to connect the remote control of the application.

The disadvantage of the closest technical solution is the relatively low reliability when working under conditions of exposure to microwave radiation, as well as the low quality of the formation of a visible image due to distortion under the conditions of its powerful effect.

The objective of the invention is the creation of a thermal imaging receiver module with increased reliability when working under conditions of exposure to microwave radiation, as well as improving the quality of the formation of visible radiation in these operating conditions.

The required technical result is to increase reliability when working under conditions of exposure to microwave radiation, as well as to improve the quality of formation of visible radiation in these operating conditions.

The problem is solved, and the required technical result is achieved by the fact that, in the thermal imaging module containing a lens in the focal plane of which an infrared detector is installed, according to the invention, a microwave filter is introduced, made in the form of a circular waveguide with an inner diameter of at least λ / 2, and a length λ, moreover, the lens is mounted inside the circular waveguide with a nut at a distance of 1 to 100 mm from the waveguide inlet through a gasket of conductive shock-absorbing material installed between the lens and the circular waveguide.

In addition, the required technical result is achieved by the fact that the round waveguide is made of brass.

In addition, the required technical result is achieved by the fact that the inner diameter of the circular waveguide lies in the range from 5 to 50 mm.

In addition, the required technical result is achieved by the fact that the outer diameter of the circular waveguide lies in the range from 20 to 150 mm.

In addition, the required technical result is achieved by the fact that the length of the circular waveguide is from 20 to 300 mm.

In addition, the required technical result is achieved by the fact that conductive rubber is used as a conductive shock-absorbing material.

The drawing shows a thermal imaging module.

In the drawing are indicated: 1 - microwave filter; 2 - gasket of conductive shock absorbing material; 3 - lens; 4 - a nut.

The thermal imaging module contains a lens 3, in the focal plane of which an infrared detector is installed (not shown in the drawing), as well as a microwave filter 1, made in the form of a circular waveguide with an inner diameter of at least λ / 2, and a length λ, and lens 3 is attached inside a circular waveguide at a distance of 1 to 100 mm from the entrance of the circular waveguide through a gasket 2 of conductive shock absorbing material, installed between the lens 3 and the circular waveguide 1, and is fixed in the round waveguide with a nut 4.

The round waveguide 1 can be made of brass coated with nickel or zinc, its inner diameter is selected in the range from d = 5 ... 50 mm depending on the wavelength of the optical filter, the outer diameter is selected in the range D = 20 ... 150 mm, and length L = 20 ... 300 mm.

As a conductive shock absorbing material, conductive rubber can be used.

The thermal imaging module operates as follows.

Received IR radiation enters through the lens 3 to an infrared detector and then to the necessary processing and display units of the thermal image.

When working under conditions of exposure to microwave radiation from transmitting phased array antennas, the radiation power can reach 10 ⁴ W / m ² . Therefore, to ensure sanitary standards for the safe operation of the thermal imaging module, it is necessary to provide a level of shielding of at least 10 ⁵ or 50 dB. To protect the optical part of the thermal imager, it is necessary to use a filter that provides a sufficient level of shielding. As a filter, a microwave filter 1 in the form of a round supercritical waveguide is used.

To protect the thermal imager lens from microwave radiation with a high power flux density (more than 10 ⁴ W / m ² ), the microwave filter must ensure image transmission without distortion of the thermal image, i.e. provides a viewing angle of 25 ° depending on the distance to the measured object and has an inner diameter larger than the diameter of the lens, or another angle in the range from 6 ° to 180 °, depending on the task.

A circular waveguide with an inner diameter greater than (1/2) λ mm and a wavelength of ~ λ mm has such characteristics.

The attenuation in such a waveguide can be estimated for a wave of type H ₁₁ having λ _cr - the radius of the waveguide. The waveguide length must be at least 30.0 mm and not more than 300.0 mm.

At a wavelength of L = 70 mm, the attenuation is estimated as

At a wavelength equal to the waveguide, the attenuation is ~ 53 dB, i.e. with such a filter, the thermal imager can operate in microwave fields with BAT ~ 2 * 10 ⁴ W / m ² ≈20 kW / m ² .

Thus, thanks to the improvement of the known device, its reliability significantly increases when working in conditions of high-power microwave radiation, in particular, when monitoring radio-transparent shelters (RPU) of phased antenna arrays (PAR), and the quality of the formation of visible radiation in these operating conditions also increases, since powerful microwave radiation does not lead to changes in the physical properties of infrared detectors and other elements of thermal imagers.

Claims (6)

1. A thermal imaging module containing a lens in the focal plane of which an infrared detector is installed, characterized in that a microwave filter is introduced, made in the form of a circular waveguide with an inner diameter of at least λ / 2 and a length λ, and the lens is mounted inside the circular waveguide with a nut a distance of 1 to 100 mm from the input of the waveguide through a gasket of conductive shock absorbing material installed between the lens and the circular waveguide. 2. The device according to claim 1, characterized in that the round waveguide is made of brass. 3. The device according to claim 1, characterized in that the inner diameter of the circular waveguide lies in the range from 5 to 50 mm. 4. The device according to claim 1, characterized in that the outer diameter of the circular waveguide lies in the range from 20 to 150 mm. 5. The device according to claim 1, characterized in that the length of the circular waveguide is from 20 to 300 mm. 6. The device according to p. 1, characterized in that the conductive rubber is used as a conductive shock absorbing material.

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