RU207158U1 - Day / night monocular - Google Patents

Abstract

The proposed utility model relates to the technique of optoelectronic observation devices, in particular to monoculars. The task of the proposed utility model is to provide prompt input of service information into the field of view of the device. This problem is solved thanks to an additional input into the monocular of a radio receiver with a whip antenna connected to an OLED display, coupled with a daytime channel.

Description

The proposed utility model relates to the technique of optoelectronic observation devices, in particular to monoculars.

Known adopted as an analogue night monocular "Alpha-9022" firm FSUE NPO "Alpha" (see Geykhman I.L., Volkov V.G. Vision and security. M .: Novosti, 2009, 840 p. . 2.2.14). It consists of a lens sequentially mounted on the optical axis, an image intensifier with a microchannel plate (MCP) and an eyepiece. The disadvantages of such a device are its inability to work during the day, the inability to promptly enter service information into the field of view.

Known adopted as a prototype day-night monocular OV-50 from Sopelem, France (see Geykhman I.L., Volkov V.G. Vision and safety. M .: Novosti, 2009, 840 p. 81, Fig. 2.3 .10e). It contains a night channel, consisting of a night objective, an image intensifier tube with a MCP, a cube-prism and an eyepiece, which are sequentially installed on the optical axis of the night lens. The device also contains a day channel, consisting of sequentially installed on the optical axis of the daytime lens, a grid located in its rear focal plane, a lens turning system containing the first and second lens components, between which a flat mirror is installed, and the second lens component is optically coupled through the hypotenuse face of a prism cube with an eyepiece. The day / night monocular provides the ability to observe both at night and during the day. However, the disadvantages of the device are still the inability to promptly enter service information into the field of view.

The task of the proposed utility model is to provide operational input of service information into the field of view of the device.

This problem is solved by the fact that a day-night monocular containing a night channel, consisting of a night objective, an image converter with a microchannel plate, a cube-prism and an eyepiece, sequentially installed on the optical axis of the day lens, a grid located in its rear focal plane, a lens turning system containing a first lens component, a flat mirror and a second lens component optically coupled through the hypotenuse face of the cube-prism with an eyepiece, characterized in that a dichroic flat mirror, the device additionally contains a radio receiver with a whip antenna connected to an OLED display, the screen of which is optically coupled through a projection lens and a dichroic flat mirror with the rear focal plane of the daytime lens.

This problem is solved thanks to an additional input into the monocular of a radio receiver with a whip antenna connected to an OLED display, coupled with a daytime channel.

The block diagram of the proposed utility model is shown in the drawing Fig. 1. The device contains a night channel 1, a day channel 2. Night channel 1 contains a night objective 3, an image intensifier (EOC) 4 with a microchannel plate (MCP) 5, a cube-prism 6 and an eyepiece 7, installed in series on the optical axis. contains a daytime objective 8, a second dichroic flat mirror 9, a grid 10 installed in the rear focal plane of a daytime lens 8, a lens turning system 11, between the first 12 and second 13 lens components of which a flat mirror 14 is installed in series. The device also contains a radio receiver 15 with a whip antenna 16. The output of the radio receiver 15 is connected to an OLED display 17. Its screen is optically coupled with a projection lens 18 through a second dichroic flat mirror 9 with a grid 10.

In the night channel 1, the photocathode of the image intensifier tube 5 operates in the spectral range of 0.4-0.9 microns, and its screen - in the spectral region of 0.53-0.56 microns. The optical coating of the hypotenuse face of the cube-prism 6 transmits in the spectral region 0.53-0.56 microns and reflects in the spectral region 0.38-0.78 microns. The dichroic flat mirror 9 transmits in the spectral region of 0.38-0.78 microns reflects at a wavelength of 0.63 microns, at which the OLED screen 17 operates.

The device works as follows. When working during the day, light from the Sun, reflected from the object of observation and the surrounding background, arrives at the daytime lens 8. It creates an inverted image of the object and background in its rear focal plane on the grid 10. In this case, the light passes through the dichroic flat mirror 9. The first lens component 12 of the lens turning system 11, focused on the reticle 10, with the help of the flat mirror 14 and the second lens component 13 transmits the image to its rear focal plane, which coincides with the front focal plane of the eyepiece 7 and is optically coupled with it through the hypotenuse face of the cube-prism 6. Due to the lens turning system 11, a direct image of the object and the background is created in the front focal plane of the eyepiece 7. The operator observes the daytime image of the object and background transmitted through the cube-prism 6 and eyepiece 7.

When working at night in conditions of a normalized level of EHO ≥ 3 × 10 ^-3 lx, night channel 1 is used to ensure the search and detection of an object. which creates an image of the object and background on the photocathode of the image intensifier 4. It converts the image into a visible one and enhances it in brightness using the MCP 5. The image of the object and background is transmitted through the cube-prism 6 and is observed by the operator through the eyepiece 7.

For operational input of service information in the field of view of night channel 1 and day channel 2, a radio receiver 15 is used. Its whip antenna 16 perceives radio wave radiation sent from the command post and carries operatively changeable service information. The radio transmitter 15 converts this radiation into a video signal, which is fed to the OLED display 17. The image from its screen is transmitted to the plane of the grid 10 using the projection lens 18 and the dichroic flat mirror 9. Then this image is observed by the operator as described above.

At present, a schematic diagram of the device has been developed and its prototyping has been completed.

Thus, due to the additional input into the monocular of the radio receiver with a whip antenna connected to the OLED display, coupled with the daytime channel, operational input of the service information into the field of view of the device is provided.

Claims (1)

Day-night monocular containing a night channel, consisting of a night objective, an image converter with a microchannel plate, a cube-prism and an eyepiece, a its rear focal plane, lens turning system, containing a first lens component, a flat mirror and a second lens component, optically coupled through the hypotenuse face of the cube-prism with an eyepiece, characterized in that a dichroic flat mirror is additionally installed at the output of the daytime lens, the device additionally contains a radio receiver with a whip antenna connected to an OLED display, the screen of which is optically coupled through the projection lens and a dichroic flat mirror with the rear focal plane of the daytime lens.

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