RU50686U1 - SIGHT FOR THE TANK - Google Patents

Abstract

The utility model relates to the field of optical instrumentation, and more specifically to aiming devices, mainly for objects of armored vehicles. The objective of the utility model is to increase the accuracy of shooting when using a sight for a tank by introducing into it an integrated system for the operational control of the parallelism of the sighting axis of the sight and the axis of the gun of the tank. To solve this problem, an optical unit has been introduced into the sight for the tank, which includes an optically coupled lens and an observation system with an aiming mark, an optical unit for optical conjugation of the aiming mark of the observation system with a control mark on the tank’s gun, located in front of the lens and consisting of two optically connected two flat mirrors and a lens while the first mirror is located on the sight axis of the sight at an angle to it, and the optical unit is mounted with the possibility of output from the course of the rays of light entering the sight of the sight. The sight can be supplemented by a illuminator to illuminate the control mark on the tank’s guns, made in the form of a sequentially and optically connected light source of the visible or infrared range of the radiation spectrum and the optical projection system.

Description

The utility model relates to the field of optical instrumentation, and more specifically to aiming devices, mainly for objects of armored vehicles.

A well-known sight for a tank [1], which includes an optically coupled lens and an observation system with an aiming mark, made in the form of a grid with an aiming mark, a wrapping system and an eyepiece. The sight also includes television and thermal imaging channels, each of which contains a lens and an electronic surveillance system with an aiming mark, observed simultaneously with objects on the monitor screen. A disadvantage of the known sight for a tank is the lack of an integrated system for the operational control of the parallelism of the sighting axes of its channels and the axis of the guns of the tank, which can change directions at a high firing frequency due to heating and air temperature fluctuations, which does not allow accounting for the mismatch of these axes or alignment of the sight relative to the gun in field conditions and reduces the accuracy of firing from it.

The objective of the utility model is to increase the accuracy of shooting when using a sight for a tank by introducing into it an integrated system for the operational control of the parallelism of the sighting axis of the sight and the axis of the gun of the tank.

To solve this problem, an optical unit has been introduced into the sight for the tank, which includes an optically coupled lens and an observation system with an aiming mark, an optical unit for optical conjugation of the aiming mark of the observation system with a control mark on the tank’s gun, located in front of the lens and consisting of two optically connected two flat mirrors and a lens while the first mirror is located on the sight axis of the sight at an angle to

her, and the optical unit is installed with the possibility of output from the course of the rays of light entering the lens of the sight.

The sight can be supplemented by a illuminator to illuminate the control mark on the tank’s guns, made in the form of a sequentially and optically connected light source of the visible or infrared range of the radiation spectrum and the optical projection system.

Introduction to the sight for the tank of an optical unit for optical conjugation of the reticle of the surveillance system with a control mark on the tank’s gun, located in front of the lens and consisting of two optically coupled two flat mirrors and a lens, the first mirror being located on the sight axis of the sight at an angle to it, and also the placement of the optical unit with the possibility of withdrawing from the course of the light rays entering the sight of the sight, provides the ability to quickly control the parallelism of the sighting axis of the sight for the tank and the axis of its guns, and therefore, taking into account the observed errors in practical shooting, which leads to increased accuracy when using the inventive sight for the tank.

The introduction of a illuminator into the sight to illuminate the control mark of the tank’s gun, made in the form of sequentially and optically connected light sources of the visible or infrared range of the radiation spectrum and the optical projection system, provides control at dusk or at night, that is, with poor visibility of the gun’s control mark in the field sight sight.

Figure 1 presents a schematic diagram of the sight for the tank, figure 2 shows a view of the field of view of the sight at the time of control.

The tank sight includes (Fig. 1) a sighting channel 1, comprising a surveillance system 2 with an aiming mark located in the focal plane of the lens 3, an optical unit 4, located in front of the lens 3 and including optically coupled two flat mirrors 5 and 6, as well as a lens 7, and a illuminator 8 for illuminating a check mark on the tank’s gun,

including a sequentially and optically connected light source 9 of the visible or infrared range of the radiation spectrum and an optical projection system 10. The surveillance system can be made in the form of a reticle, an enveloping system and an eyepiece, or in the form of a video camera with a monitor and an electronic reticle forming system on the monitor screen [1]. In the first case, the illuminator 8 uses a radiation source 9 of the visible range of the spectrum. In the second case, an infrared radiation source may be used for masking purposes. Mirrors 5 and 6 are installed so that the first mirror 5 is located on the sight axis of the sight at an angle to it, the second mirror 6 is optically connected to the mirror 5 and lens 7. Lens 7 has a focal length nominally equal to the distance from the optical unit to the reference mark on guns of the tank. The sighting mark of the sighting system is optically coupled to a control mark 12 on the tank’s gun 11 using an optical unit. The optical unit 4 has the ability to output from the course of the rays of light entering the lens 3 of the sight.

The control mark 12 may be made in the form of a cut on the barrel of the gun 11, as well as in the form of a metal plate with a hole mounted on the barrel of the gun, or may have a different design.

Figure 2 shows the view of the field of view of the sight at the time of control, where pos.13 is the aiming mark of the surveillance system, pos.14 is the image of the control mark 12.

The sight of the tank works as follows.

The operator monitors the terrain using the surveillance system 2, and fires from the tank’s guns. In this case, the optical unit 4 is brought out of the light rays in the direction of the arrow shown in FIG. If necessary, to carry out operational control of parallelism between the sighting axis of the sight and the axis of the tank’s gun, the operator introduces a 4-inch optical unit into the light rays of the sight using a manual or electric drive

position fixed in figure 1. In this case, the operator will observe the sighting mark 13 (Fig. 2) and the image 14 of the control mark 12 of the gun 11 of the tank in the field of view. In the above example, the image 14 of the control mark 12 has the form of a round spot, which is the image of the hole in the plate, mounted on the barrel of the tank guns. It may be dark or light depending on the lighting conditions. If the visibility of the image 14 is poor, then the operator can turn on the illuminator 8 and provide improved visibility of the image of the reference mark. If violation of the parallelism of the sighting axis of the sight did not occur during operation of the tank or during firing, then the image of the control mark 14 will coincide with the top of the aiming mark 13, as shown by the dotted line in figure 2. In this case, the alignment of the sight relative to the gun is not required and you can continue to work without the introduction of angular corrections. Otherwise, corresponding to FIG. 2 (image 14 is shifted away from the top of the aiming mark), to ensure accurate shooting, either alignment of the sight relative to the gun or introduction of appropriate angular corrections when aiming is necessary. If there is a built-in reconciliation system, the operator, using appropriate drives, combines the image 14 of the control mark on the barrel of the object’s gun with the top of the aiming mark, eliminating the imbalance of the sighting axis of the observation system and the axis of the tank’s guns. In the absence of such a system, the operator can take into account errors that have appeared at least by eye, guided by the strokes of the angular scale in the field of view of the device. In both cases, improved accuracy is achieved.

Thus, the proposed sight for the tank due to the introduction of an optical unit into it, which allows for the operational control of the parallelism of the sighting axis of the observation system and the axis of the tank’s guns, provides a solution to the problem of increasing firing accuracy.

Information sources

1. Patent RU No. 2191971. Sight - a guidance device with radiating channels and a method for reconciling the parallelism of optical axes. Publ. 10/27/2002, Bull.№30

Claims (3)

1. The sight for the tank, which includes an optically coupled lens and an observation system with an aiming mark, characterized in that an optical unit is introduced for optical pairing of the aiming mark of the observation system with a control mark on the tank gun, located in front of the lens and consisting of two optically coupled flat mirrors and lenses, while the first mirror is located on the sight axis of the sight at an angle to it, and the optical unit is installed with the possibility of output from the rays of light entering the lens of the sight. 2. The sight according to claim 1, characterized in that it is supplemented by a illuminator to illuminate the control mark on the tank guns. 3. The sight according to claim 2, characterized in that the illuminator is made in the form of sequentially and optically coupled light sources of the visible or infrared range of the radiation spectrum and the optical projection system.