RU2191971C2 - Sight-guidance device with radiation channels and manner of test of parallelism of optical axes - Google Patents

Abstract

FIELD: optical guidance instruments employing various types of lasers as radiation source in information channel. SUBSTANCE: invention can find use in complexes of guided rockets. Technical result of invention lies in rise of quantitative indices of sight-guidance device and its summary usefulness due to reduced effect of temperature deformations on position of optical axes of information and infrared channels. Sight-guidance device with radiation channels includes information and sight channels, collimator of sight mark additional infrared and TV channels with monitors and reflection-prism system for radiation input into these channels. Collimator is mirror-type collimator. Manner of test of parallelism of optical axes of sight-guidance device consists in match of test radiation of information channel with test mark of sight channel. TV channel is used in addition as sight channel. Radiation from mirror collimator with diaphragm is directed by reflection-prism system into infrared and TV channels. Radiation of information channel is directed into TV channel. Test compensator of information channel is employed to match image of radiation of information channel with image of diaphragm of mirror-type collimator on screen of monitor of TV channel. Sight mark is formed in this case on screen of monitor of infrared channel in point of image of diaphragm. EFFECT: raised quantitative indices of sight-guidance device. 2 cl, 1 dwg

Description

 The invention relates to optical guidance devices in the optical beam of machines and, in particular, aircraft, using various types of lasers as radiation sources in information channels.

 Aiming the radiation of the information channel on the target is carried out in the daytime and at night with the help of a daytime sighting device and a thermal imager, the optical axis of which should be parallel to the optical axis of the information channel. Ensuring the parallelism of the optical axes in all operating conditions of the sight-pointing device is a complex technical problem, which is solved by using a special alignment method. The working spectral range of the thermal imaging channel does not allow the use of existing reconciliation methods based on projection of the alignment mark formed in the information channel into the sight.

 Known sight-guidance device containing an information channel with an emitter, pancratic system and lens, a sighting channel with a grid, a head mirror with a device for its guidance, stabilization and an electronic control unit, an electron-optical converter (EOC) with an amplifier and an aiming collimator.

 When the sighting device is a guidance device in the day mode, it is possible to observe the terrain and the target through the daily sighting channel, aiming and aiming the guided projectile at the target using the control information field. In this case, the grid is installed in the image plane of the lens and has verified strokes and reticle. The wrapping system transfers the image of the grid and the target to the focal plane of the eyepiece.

 When the aiming sight device is in night mode, the lens forms an invisible image of the terrain and target on the image intensifier photocathode. The image converter converts an invisible image into a visible one, which is observed by the operator through a magnifying glass. To conduct targeted shooting in the field of view of the night channel, an aiming mark is projected through the collimator.

 The parallelism of the optical axes of the information and sighting channels is verified by highlighting the alignment strokes of the information channel raster with visible light and projecting their images with a pancratic system, a lens and a prism into the sighting channel, followed by aligning the image of these strokes with the verified lines of the sighting channel grid. The alignment of the optical axes of the information and night channels is not performed, since in night mode guidance of guided projectiles is not provided.

 This sight-targeting device is selected as a prototype [1].

 The disadvantage of the prototype is that the optical system does not provide for the firing of guided projectiles in night mode. If a thermal imaging channel is introduced into the device’s design, which provides a significantly greater target detection range and target tracking, the system for reconciling the optical axes parallelism cannot be used in the aiming device, since the device’s design does not contain a device for reconciling the parallel axes of the information and thermal imaging channels. The lack of alignment of the optical axes of these channels significantly reduces the total effect of the operation of the optical guidance system in night mode.

 The existing method for reconciling the parallelism of the optical axes involves projecting the alignment lines of the information channel illuminated by visible radiation into the sighting channel and combining them with the strokes of the sighting grid. Since the night channel is designed to work only with cannon weapons, the alignment of the optical axes for night mode is not provided.

 The disadvantage of the alignment method existing in the prototype is that it is completely unsuitable for aligning the optical axes of the information and thermal imaging channels, since the radiation of the alignment of the information channel does not correspond to the working spectral range of the thermal imaging channel.

 The objective of the invention is to improve the quality indicators of the sight-guidance device and its total final effect by reducing the influence of temperature deformation on the position of the optical axes of the channels.

 This object is achieved by the fact that in the sight-pointing device with radiating channels, containing an information channel with emitters, a panoramic system and a lens, a sighting channel with a grid, a head mirror with a device for its guidance, stabilization and an electronic control unit, an electron-optical converter with an amplifier and an aiming mark collimator, thermal-imaging and television channels with monitors and a mirror-prism radiation input system into these channels are introduced, while the collimator is made mirror-like.

 Moreover, in the method for reconciling the parallel optical axes of the sighting device, the guidance device, based on combining the reconciliation radiation of the information channel with the alignment mark of the sighting channel, it additionally uses the television channel as the sighting channel, while the radiation from the mirror collimator with the diaphragm is guided by a prism-mirror system in the thermal imaging and television channels, the radiation of the information channel is sent to the television channel, then the information channel is verified by the compensator and combine on the monitor screen of the television channel the image from the radiation of the information channel with the image of the aperture of the mirror collimator, while on the monitor screen of the thermal imaging channel in place of the image of the diaphragm, an aiming mark is formed.

 The proposed guidance device and method for reconciling the parallelism of the optical axes of the information and thermal imaging channels can improve technical performance with an increase in the total effect in all operating conditions of the guidance device. This ensures the simplicity of reconciliation, since the diaphragm of the collimator and the image of the radiation of the information channel are simultaneously displayed on the monitor screen of the television channel.

 A search conducted in patent and scientific and technical literature showed that the claimed combination is unknown, i.e. it meets the condition of patentability “novelty”.

 Since the known target components are included in the aiming device and there is a need for such systems, the claimed one corresponds to the level of "industrial applicability".

 Due to the fact that as a result of using this aiming device, there is a higher cumulative effect, the presence of which is obvious, the claimed aiming device and method of alignment of the optical axis of the information and thermal imaging channels correspond to the condition of "inventive step".

 Figure 1 presents the composition of the sight-guidance device, comprising a head mirror 7 with a guidance device, stabilization 8 and an electronic control unit 9, a sighting channel 5 with a grid 6, a collimator 10, in which the diaphragm 18 and c are illuminated with a radiation source 20 with a reflector 21 Using a mirror lens 22 and a mirror with a hole 23, a parallel radiation beam is formed, directed by a mirror 15 into a thermal imaging channel 11 with a monitor 13, and a prism 16 into a television channel 12 with a monitor 14, into which, when the prism 16 is switched through a prism 17 apravlyaetsya radiation information channel 1 from the radiators 2 through the condensers 24, the beam splitter unit 25, a system of zoom lens 3 and 4.

 The method of reconciling the parallelism of the optical axes of the sight-pointing device is as follows.

A source of radiation 20 of a wide spectral range with a reflector 21 highlights the alignment mark located in the focal plane of the mirror lens 22, for example, aperture 18, and the radiation through the hole in the mirror 23 enters the mirror lens 22, forming a parallel beam, which is directed by the mirrors 23 and 15 into the thermal imaging channel 11. On the screen of the monitor 13 at the place of the image of the aperture of the collimator, an image of the reticle of the thermal imager is formed, which determines the position of its optical axis. By prism 16, the radiation of the collimator 10 is directed to the television channel 12 in the spectral operating range of the TV and the image of the diaphragm (alignment mark) of the collimator 10 is formed on the screen of its monitor 14. Since the image of the diaphragm in the television channel 12 is formed by the same collimator 10 and mirror 15 as a thermal imaging, and the prism 16 (BS ^0-o) does not introduce errors in the climatic and mechanical action, the position of the aperture image 18 on the monitor television channel 12 also determines the position of the optical axis eplovizionnogo channel 11, i.e. the optical axes of these channels are parallel, the prism 16 is then switched to the side information channel 1, the electronically stored on the screen 14 the image of the diaphragm 18.

When injection lasers 2 are used in the information channel 1, their radiation through the condensers 24, the beam splitter 25, the panoramic system 3, the lens 4, and the prisms 17, 16 are sent to the television channel 12, the radiation image in the form of a “cross” is formed on the monitor screen 14, center which the alignment compensator 19 is combined with the image of the diaphragm 18 of the collimator 10. And since the position of the image of the diaphragm on the monitor screen of the television channel determines the position of the optical axis of the thermal imaging channel 11, the optical axis the information channel is installed parallel to the optical axis of the thermal imaging channel 11. Prism 17 (BkR-180 ⁰ ) as well as the prism BS-0 ^{o is} stable during operation.

 When forming the control field of the information channel in another way, illumination can be performed, for example, of a raster installed in the subject plane 26 of the pancratic system 3 and its alignment pattern is projected through the same optical system into a television channel, where on the monitor screen 14 it is combined with the image of the aperture of the collimator 10.

 The solution of this problem allows us to significantly improve the quality indicator of the aiming device and its total beneficial effect, which consists in expanding its operational parameters by introducing a thermal imaging channel into the scope of the aiming device, which ensures firing of guided projectiles in night conditions.

 The proposed method for reconciling the parallelism of the optical axes can significantly reduce the influence of temperature deformations on the position of the optical axes by visualizing the position of the optical axes of the thermal imaging and information channels in the television channel and ensuring their parallelism by the reconciliation compensator.

Sourse of information
1. Aiming device 1K13. Technical description and operating instructions 1527.00.00.000TO, 1987, State Unitary Enterprise "KBP", Tula.

Claims (2)

 1. A sight-pointing device with radiating channels, containing an information channel with emitters, a pancratic system and a lens, a sighting channel with a grid, a head mirror with a device for its guidance, stabilization and an electronic control unit, an electron-optical converter with an amplifier and an aiming collimator, characterized in that thermal imaging and television channels with monitors and a mirror-prismatic system for introducing radiation into these channels are introduced into it, while the collimator is made mirror-like.  2. A method for reconciling the parallel optical axes of an aiming sight device based on combining the verified radiation of the information channel with the alignment mark of the sighting channel, characterized in that the television channel is additionally used as the sighting channel, while the radiation from the mirror collimator with the diaphragm is guided by a prism-mirror the system into the thermal and television channels, the radiation of the information channel is sent to the television channel, then the reconciliation compensator of the information channel aligned on the screen of the monitor television channel image information from the radiation channel depicting aperture collimator mirror, wherein the thermal channel on the screen in place of the diaphragm image is formed the reticle.