RU190132U1 - Thermo Video Recording Device - Google Patents

Abstract

The invention relates to the field of video transmission. Thermovideo registration device contains two video cameras with periscopic mirror devices, one of which is a photo-registering device with a wavelength range from 0.3 to 1.0 μm and a lens made of quartz glass, and the other is a video camera with a wavelength range from 1.1 to 5 , 3 microns, equipped with an optical silicon lens, while the video cameras are combined in a single package with a thermal insulation shell, on top of which is a titanium radiation protection shell. The technical result consists in obtaining information about the thermal position in the zone of thermally loaded elements of spacecraft in the wavelength range from infrared to ultraviolet by means of video telemetry. 4 hp f-ly, 4il.

Description

The invention relates to the field of video transmission and can be used in the construction of video control devices operating under conditions of strong ionizing radiation, for example, on board spacecraft.

In the prior art, a video monitoring device is known in areas with an increased level of ionizing radiation (patent of the Russian Federation for utility model RU 148690). This device is intended for continuous video monitoring in areas with high levels of ionizing radiation and neutron exposure with continuous recording and the creation of an archive of video data. The utility model is a modular design device placed in a sealed enclosure protected from ionizing radiation and neutron effects, consisting of functional modules: a television camera module, a digital conversion module, an information exchange module, an interface module, a control and recording module, a backup power module, a unit battery pack. A television camera module that contains an analog television camera installed at an angle of 90 ° to the direction of view with a deflection of the optical axis of the camera by 90 ° using a mirror installed at an angle of 45 ° and placed in a separate housing.

The closest analogue of the proposed technical solution is a television camera designed for systems of visual remote monitoring of the outer and inner surfaces of the reactor vessel (patent of the Russian Federation for utility model RU 150289). This device relates to television cameras for systems of visual remote monitoring of the outer and inner surfaces of the reactor vessel.

Television camera, contains a housing made of radiation-resistant material containing tungsten, with a protective casing made of stainless corrosion-resistant steel, and an optical image conversion unit into an electrical signal placed in the housing, a lens, a diaphragm correction unit installed in front of the lens, a window from radiation-resistant glass, made in the body wall, and a mirror optically associated with the lens and window, and the camera body and the mirror body are made of alloy VNZH-95 (alloy containing 95 wt.% tungsten, the rest is nickel and iron), and the reflecting surface of the mirror is made of a silicon wafer fixed in the mirror case, the power supply unit of the conversion unit is removed from the optical-image conversion unit into an electrical signal, the correction unit additionally contains two light filters, one of which Blue-green is designed to work in the visible light range, and the other is in the infrared range and is made of silicon, and an electric motor operating in relay mode and configured to eklyucheniya silicon filter, simultaneous operation of two filters allocates a wavelength for a television camera 850 nm with a bandwidth of 0.7 ~ 50 nm.

The disadvantages of the known devices is not a sufficiently wide range of wavelengths of the recorded signals, which does not allow for a complete picture of the thermal situation in the observation area.

The technical result, the solution of which the claimed technical solution is aimed at, is obtaining information about the thermal position in the zone of thermally loaded elements of spacecraft in the wavelength range from infrared to ultraviolet by means of video telemetry.

The technical result is achieved by the fact that when the video recording device is located near thermally loaded spacecraft elements, it is proposed to use two video cameras aimed at one about the same area of view of the object, one of which is a photo-recording device in the wavelength range from 0.3 to 1.0 μm ( for example, a charge-coupled device with a “virtual” phase (VFPSS) [3] and a quartz glass lens, another video camera with a photo-registering device in the wavelength range from 1.1 to 5.3 microns (for example, an infrared photo recorder a tactile instrument (IR CCD) [3] or a cadmium-mercury-tellurium receiver (КРТ)) and an optical silicon lens [5].

These cameras have the necessary elements for thermal protection from overheating and cooling, and to protect against the effects of radiation factors of lenses of lenses and photo-registering devices use a periscopic device, the socket of which is made of titanium with a reflecting mirror (at an angle of 45 °) made of nickel located on the main optical axis lens.

Figure 1 shows the construction of the thermal imaging device, where the video cameras are oriented towards each other:

1 - photo-registering device with a range from 0.3 to 1.0 μm;

1a — photo-registering instrument with a range from 1.1 to 5.3 μm;

2 - camera lens with a range from 0.3 to 1.0 microns;

2a — camera lens with a range from 1.1 to 5.3 μm;

3 - thermal protection of a video camera with a range from 0.3 to 1.0 μm;

3a - thermal protection of a video camera with a range from 1.1 to 5.3 microns;

4 - periscopic mirror of the camera with a range from 0.3 to 1.0 μm;

4a — periscope mirror of the camera with a range from 1.1 to 5.3 μm;

5 - radiation protection shell;

6 - video camera with a range from 0.3 to 1.0 microns;

6a - video camera with a range from 1.1 to 5.3 microns.

Thermal protection 3 (3a) consists of a heat-insulating shell made of dense stone wool [4], radiation protection is provided by a titanium shell 5 over thermal protection.

Since the periscope mirror can be positioned close enough to the camcorder lens, but in order not to touch the lens itself, and the lens and photo registration device must be protected from direct radiation, the distance from the lens center to the mirror (on the main optical axis) is equal to the distance from the center of the lens to the center of the diagonal of the photosensitive zone of the CCD [1, 2], i.e.

ƒ _min = ƒ + ƒ ',

where ƒ is the focal length of the objective lens, ƒ 'is the distance from the focus of the objective lens to the center of the diagonal of the CCD photosensitive area.

The length of the periscope socket at the bottom will be equal to the focal length of the objective lens ƒ, and the remaining distance to the periscope mirror on the main optical axis,

ƒ _min -ƒ = ƒ + ƒ'-ƒ = ƒ '.

The device works as follows (Fig. 2): the video image of the considered area is projected onto the mirror. Next, the projected image gets on the lens of the video camera and through the lens on the photo-registering device.

Video cameras of the video recording device can be located parallel to each other inside a rectangular parallelepiped using radiation protection (Fig. 3). When receiving information from one image field of an object from two video cameras, it is required that the main optical axes of video camera lenses pass through the periscope mirrors through a single point on the object being monitored. For this mirror, the periscopes are turned at an angle γ / 2 towards each other [2], while the ends of the periscopes with the mirrors should be located on the same plane. For both camcorders должно _min must be the same. Also, the minimum distance from the main optical axis to the center of the object ƒ _2min (or the minimum distance from the center of the periscope mirror to the center of the image field) will be the same.

With the distance of the object from the video recorder, the angle of rotation of the periscope mirrors is significantly reduced, therefore, for low-resolution CCD applications or video systems with a high video compression ratio, the angle of rotation of the mirrors can be neglected. In this case, it is proposed to use a common periscope 7 with a common mirror 8 (Fig. 4).

The use of the proposed video recorder provides measurement of the temperature parameters of thermally loaded spacecraft installations in the wavelength range from infrared to ultraviolet under conditions of exposure to ionizing radiation.

Bibliography

1 Landsberg G.S. - "Optics" - 5th ed. - M .: Science, 1976.

2 Fedosov I.V. - “Geometric Optics” - Saratov: Satellite, 2008, 92 p.

3 G.I. Vishnevsky, M.G. Vydrevich, V.K. Nesterov, V.L. Rivkind - "Domestic UV and IR FPZS and digital cameras based on them." Journal "Electronics: science, technology, business" - 8/2003, p. 18-24.

4 GOST 31913-2011.

5 Korotaev, V.V. Basics of thermal imaging / V.V. Korotaev, G.S. Melnikov, S.V. Mikheev. - SPb .: St. Petersburg National Research University of Information Technologies, Mechanics and Optics, 2012. - 123 p.

Claims (8)

1. Thermovideo recording device containing two video cameras with periscopic mirror devices, one of which is a photoregistrant with a wavelength range of 0.3 to 1.0 μm and a quartz glass lens, and the other is video camera with a wavelength range from 1.1 to 5.3 microns, equipped with an optical silicon lens, while video cameras are combined in a single package with a heat-insulating sheath, on top of which is a titanium radiation protection sheath. 2. Thermovideo-recording device according to claim 1, characterized in that the video cameras are located on the same plane and are oriented along the same axis towards each other by periscopic systems. 3. Thermovideo recording device according to claim 1, characterized in that the video cameras are located in the same plane, parallel to each other. 4. Thermovideo registration device according to claim 3, characterized in that the video cameras have a common periscope with a single mirror. 5. Thermovideo-registration device according to claim. 1, characterized in that the insulating sheath is made of stone wool.

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