RU2805387C1 - Target simulator of large armoured vehicles - Google Patents

Abstract

FIELD: range equipment.

SUBSTANCE: invention relates to targets simulating real objects, such as tanks, for example, intended for training in shooting at moving ground objects. A target simulator of large-sized armored vehicles contains a support surface located on a movable platform with a spatial frame structure installed on it in the form of a rectangular parallelepiped frame having an upper horizontal rectangular element connected to vertical posts, and target shields placed on the side surfaces of the frame, equipped with imitation means of various signatures simulated object in the corresponding projections. The supporting surface is made with the possibility of rotation relative to the vertical axis, the connections of the vertical posts of the frame structure with the supporting surface and the upper horizontal rectangular element of the frame are made hinged to ensure rotation in a plane perpendicular to the longitudinal axis of the supporting surface.

EFFECT: ensuring the possibility of the unexpected appearance of a target in a given location of the target field of a firing range/shooting range, as well as a higher degree of credibility.

1 cl, 5 dwg

Description

The proposed invention relates to range equipment, specifically to targets simulating real objects with given signature characteristics, intended for training in shooting at moving ground objects.

A number of targets are known in the form of a profile projection of a real target [1, 2], simulating a tank. In particular, a thermal target [1] is designed to simulate a target in the visible, infrared and ultraviolet regions. The target consists of five modules, each of which is a welded riveted structure made of steel plates mounted on aluminum profiles. On the back side of the plates, in areas simulating the heating of real targets, flexible heating elements are glued, the heating temperature of which is controlled using a programmable logic controller for three heating options: a tank target with a warm engine without moving; in move; in motion with shooting. The target simulator has a similar design [2].

A common disadvantage of such devices is the one-dimensional design of target shields, mainly displaying only a profile projection of the target object, which does not allow achieving high credibility of targets and the possibility of their full use for training using modern weapons equipped with homing heads (GOS). It should be noted that, for example, anti-tank missile systems (ATGM) of the FGM-148 “Javelin” type are aimed at vertical projections of the target, and its destruction is carried out from the upper hemisphere to the horizontal projection. In addition, the widespread use of unmanned aerial vehicles in modern military conflicts has also shown the possibility of hitting such targets from this angle.

Along with the above-mentioned one-dimensional (“profile”) targets, recently there have been developments of target installations that imitate targets in a three-dimensional (volumetric) representation.

Thus, patent [3] presents an inflatable target simulator of a vehicle/launcher of a tactical missile, while patent [4] presents a full-size volumetric target of the main tank of Taiwan SM-11 (M48N), mounted on the basis of a frame frame.

The main disadvantage of these targets is the high production costs, in the case of inflatable targets - low maintainability, and in addition, the initially stationary location on the ground and the absence of the effect of their rapid and relatively unexpected appearance (rise) within the target field of the firing range/shooting range.

The closest to the proposed invention in terms of technical essence and achieved result is a target installation [5], containing a support surface located on a movable platform with a spatial frame structure installed on it in the form of a rectangular parallelepiped frame having an upper horizontal rectangular element connected to vertical posts, and target shields placed on the side surfaces of the frame, equipped with imitation means of various signatures of the simulated object in the corresponding projections.

Despite its placement on a mobile carrier, this target installation, like the above analogues, also lacks the element of unexpected rapid appearance (rise) in a given location of the target field of the training ground/shooting range. The design of the installation provides for preliminary stationary fastening of target shields to it, and subsequent movement in an already assembled state.

The upper horizontal rectangular element of its frame structure can only move vertically, and the vertical posts are installed permanently and motionlessly. Therefore, even when using target shields made of flexible fabric or film materials, there will be no effect of the unexpected appearance of a target when lifting the upper horizontal rectangular element of the frame structure attached to them, because the vertical posts will be constantly in sight, and the location of the target’s appearance can be easily determined visually from them.

In addition, the absence of signature features of the simulated object on the upper surface of the frame structure of this target installation (visual horizontal projection or top view), as well as in analogue targets, does not allow achieving high credibility of the target and the possibility of its full use for training using modern ammunition equipped with a seeker and capable of destroying armored vehicles from the upper hemisphere.

The technical objective of the proposed invention is to eliminate the noted disadvantages - to ensure the possibility of the unexpected appearance of a target in a given location of the target field of a training ground/shooting range, as well as a higher degree of plausibility.

The solution to the problem is achieved by the fact that in a known target simulator of large-sized armored vehicles containing a support surface located on a movable platform with a spatial frame structure installed on it in the form of a frame of a rectangular parallelepiped, having an upper horizontal rectangular element connected to vertical posts, and placed on the side surfaces frame with target shields, equipped with imitation means of various signatures of the simulated object in the corresponding projections, in accordance with the invention, the supporting surface is made with the possibility of rotation relative to the vertical axis, the connection of the vertical posts of the frame structure with the supporting surface and the upper horizontal rectangular element of the frame is made hinged to ensure rotation in the plane perpendicular to the longitudinal axis of the supporting surface, the end elements of the frame structure contain additional frames installed at an angle to the vertical, also hingedly connected to the upper horizontal rectangular frame element, and in contact with the supporting surface by means of sliding supports, while on the upper horizontal rectangular frame element there is an additional horizontal projection of the simulated object, in turn equipped with imitation means of its various signatures.

The necessity and sufficiency of the above distinctive features of the proposed technical solution can be explained as follows.

The design of a support surface located on a movable platform with the ability to rotate about a vertical axis allows you to orient the target installation at a given angle (angle) to the direction of action of the weapon (artillery, missile, small arms) used by personnel during training/training. For example, with simultaneous visual demonstration of profile and frontal projections of the simulated object.

Due to the large dimensions of the simulator target, its supporting surface can be placed, for example, on a railway platform moved along the appropriate track located behind a protective parapet, or on another movable carrier.

The hinged connection of the vertical posts of the frame structure with the supporting surface and the upper horizontal rectangular element of the frame, ensuring rotation in a plane perpendicular to the longitudinal axis of the supporting surface, makes it possible to “fold” the entire structure, covertly move it on a moving platform to a given location of the target field of the firing range/shooting range, and subsequent unexpected appearance upon ascent.

Additional frames placed on the end elements of the frame structure, installed at a slight angle to the vertical, serve to mount on them target shields with imitation means of various signatures of the simulated object in the front and rear projections. And their connection to the upper horizontal rectangular element of the frame is hinged, along with the presence of sliding supports in contact with the supporting surface, allowing for proper folding of the frame structure.

With a small angle of inclination of the frames to the vertical within 15°, the distortion in the height of the corresponding projections does not exceed 3.5%.

Placing an additional horizontal projection (top view) of a simulated object on the upper horizontal rectangular element of the frame, equipped with simulating means of various signatures, increases the degree of plausibility of the target installation, ensures its conditional three-dimensionality, and allows its use for training using modern ammunition equipped with a seeker, and carrying out defeating armored vehicles from the upper hemisphere.

Elements of the frame structure can be made of radiotransparent materials - plastics, wood, etc., with a cross-sectional profile that provides the necessary strength characteristics.

The target shields used in the installation can be equipped on their rear sides with local heating sources that imitate the thermal signature of the object, and on the external sides with its images against the background of the environment (depending on the conditions of use), providing, through the selection of paints, the corresponding signature in visible and ultraviolet ranges, as well as corner reflectors or fine metallic paint fillers to simulate radar signatures. Foil plastic sheets, plywood, textile and film materials, etc. can be used as target shield material.

The invention is illustrated by the following graphical information: FIG. Figure 1 shows, as an example, a schematic diagram of a spatial frame structure in the form of a rectangular parallelepiped frame mounted on a supporting surface, as well as design options for target shields indicating their installation locations.

In fig. 2 - schematic diagram of the frame structure during folding.

In fig. 3 - top view of a folded simulator target.

In fig. 4, 5 - view of the simulator target from different angles.

To simplify the images, the movable carrier platform of the simulator target, as well as the drive mechanisms for rotating the supporting surface and lifting the vertical posts of the frame structure are not shown in the illustrations. In addition, for the same purpose, the illustrations do not indicate means for simulating radar signatures, but in FIG. 4 and 5 - small angles of inclination of the end target shields.

The following explanation of the design corresponds to the simulator target in its “unfolded” form before its use.

The simulator target (Fig. 1) contains a support surface 1 located on a movable platform with a spatial frame structure installed on it in the form of a frame of a rectangular parallelepiped 2, having an upper horizontal rectangular element 3 connected to vertical posts 4. Target shields are placed on the side surfaces of the frame 5, 5', 5'', equipped with imitation means of various signatures of the simulated object in the corresponding projections - profile (main view) 5, frontal (left view) 5', rear (right view) 5''. A target shield with a horizontal projection of the simulated object (top view) 5''' is placed on the upper horizontal rectangular element of the frame 3 (see also Fig. 4, 5).

The supporting surface 1 is made with the possibility of rotation relative to the vertical axis 6. The vertical posts of the frame structure are connected to the upper horizontal rectangular element of the frame and the supporting surface by means of hinges 7 and 8, providing rotation in a plane perpendicular to the longitudinal axis of the supporting surface 9. The end elements of the frame structure contain additional frames 10, installed at a slight angle to the vertical. Their connection with the upper horizontal rectangular element of the frame is made through hinges 11, and contact with the supporting surface is made on sliding supports 12.

If necessary, due to the possibility of rotating the supporting surface 1 relative to the vertical axis 6, the simulator target can be installed to provide different viewing angles of the side target shields 5, 5' and 5'' (Fig. 4, 5).

When folding the simulator target into a hidden position (Fig. 2), the racks of the frame 4, together with the target shield 5 fixed on them (Fig. 1, 4, 5), by means of their own drive, are rotated along the axes of the hinges 8 to the supporting surface 1 in the perpendicular direction longitudinal axis 9. In this case, the upper horizontal rectangular element 3, which has a hinged connection 7 with the posts 4, together with the target shield 5'' placed on it, makes plane-parallel movement in the horizontal and vertical directions to the supporting surface 1.

Simultaneously with the rotation of the posts 4 and the accompanying movement of the rectangular element 3, the frames 10 with target shields 5' and 5'', installed at a slight angle to the vertical on the end elements of the frame structure 2, thanks to the hinge joints 11, also rotate relative to the upper horizontal rectangular element 3. The sliding supports 12 of the frames 10 in contact with the supporting surface 1 ensure free movement of the lower surfaces of the frames along it in a direction both parallel (vector a _x ) and perpendicular (vector a _y ) to the longitudinal axis 9 of the supporting surface 1, i.e. . as shown for the left frame 10 (Fig. 2), in the direction of the resulting vector a _p .

The rotation of the racks 4 is carried out until the target shield 5 is laid on the supporting surface and covered with the target shield 5'''. At the same time, frames 10 with target shields 5' and 5'' are also laid on the supporting surface. As a result, when folded, the simulator target has a top view, shown in Fig. 3.

Bringing the simulator target into working position is carried out by rotating the racks 4 from a horizontal to a vertical position, with simultaneous angular and linear movements of structural elements in directions opposite to those described above. The speed at which the target rises from the hidden state to the working state will be determined by the power of the drive for turning the racks.

If there are local heating sources on the back sides of the target shields 5...5''' to reproduce the thermal signatures of the simulated object, the corresponding heating can be carried out when the target is folded, before it is raised. And the rotation of the supporting surface to the required angle position is after lifting.

Thus, this design of the simulator target provides the possibility of the unexpected appearance of a target in a given location of the target field of the training ground/shooting range. In addition, placement on the upper horizontal rectangular element of the frame of the target shield with an additional horizontal projection (top view) of a simulated object, equipped with imitation means of various signatures, increases the degree of credibility of the target, and allows it to be used for training using modern ammunition equipped with a seeker that carries out destruction object from the side of the upper hemisphere.

Sources of information taken into account when completing the application:

1) Utility model of the Russian Federation No. 158373 Thermal target, F41J 1/08, 2015

2) German patent DE3930914A1 Shooting target raising mechanism -incorporates spring accumulator corked by motor-driven lever mechanism, F41J 7/00, 1991.

3) PRC patent CN212870919U Missile launching vehicle inflation simulation target, F41J 1/08, F41J 1/10, 2020.

4) PRC patent CN 216668431 U Modularized M48H main battle tank target, F41J 1/08, 2021.

5) UK patent GB 2204112 A Target device, F41J 9/02, 1988 - prototype.

Claims (1)

A target simulator of large-sized armored vehicles, containing a support surface located on a movable platform with a spatial frame structure installed on it in the form of a rectangular parallelepiped frame having an upper horizontal rectangular element connected to vertical posts, and target shields placed on the side surfaces of the frame, equipped with imitation means of various signatures of the simulated object in the corresponding projections, characterized in that the supporting surface is made with the possibility of rotation about a vertical axis, the connections of the vertical posts of the frame structure with the supporting surface and the upper horizontal rectangular element of the frame are made hinged to ensure rotation in a plane perpendicular to the longitudinal axis of the supporting surface, end elements of the frame structure contain additional frames installed at an angle to the vertical, also hingedly connected to the upper horizontal rectangular frame element, and in contact with the supporting surface by means of sliding supports, while on the upper horizontal rectangular frame element a horizontal projection of the simulated object is additionally placed, in turn equipped with imitation means of its various signatures.