RU2442947C1 - Air target imitator - Google Patents

Abstract

FIELD: military equipment.

SUBSTANCE: invention refers to means of air target imitation, particularly to moving air target imitators. The imitator includes rocket engine with stabilizers and warhead. The warhead includes inserted tracers of forward and backward group, current sources, unit of electronic delay of tracers launching. Imitator is equipped with rotation tail unit around lengthwise axis made as flat fins. The fins are fixed radially at the engine behind the stabilizers, under an angle to lengthwise axis. The tracers of backward group are fixed at the engine and oriented with their operation faces backwards. Tracers of back group are launched from start station with imitator start. Tracers of forward group are located in the warhead, oriented with their operating faces forward. Tracers of the forward group are launched with delay unit from on-board power source. Tracers of each group are located symmetrically to lengthwise axis of air target imitator.

EFFECT: extension of possibilities of air target imitator.

4 cl, 1 dwg

Description

The invention relates to means of simulating air targets, in particular to mobile simulators of air targets (IVC), and can be used to refine technical characteristics, control the technical conditions of anti-aircraft systems with various guidance systems (photo-contrast, infrared, radar), as well as for training calculations mentioned complexes when conducting combat training.

The target situation for firing anti-aircraft systems is created by the use of simulators of air targets (targets) of various types, reproducing the characteristics of modern air attack equipment (STS) - aircraft, helicopters, cruise missiles: trajectory; photo-contrast; reflective in the radar range in various directions; radiative in the infrared in different directions; if possible jamming (thermal, radar), etc.

Known universal simulator of air targets (see patent RU No. 2147722, IPC F41J 9/08, 2/00, publ. 04/20/2000). A universal simulator of air targets contains a rocket engine, a stabilizing device (stabilizers), a head part with lens and corner reflectors placed in it. The simulator is equipped with a heat emitter (tracer) located in a case with a diameter of not more than 0.7 caliber with radial windows and located behind the lens reflector.

The disadvantages of this device are that:

- detection and capture of this information center by anti-aircraft missiles with thermal (operating in the infrared range) homing heads is impossible when firing “after” and “towards”, but only on a certain parameter, and only on a certain section of the trajectory, since the jet engine works only at the launch site The ITC cannot provide infrared radiation to the rear hemisphere along the entire flight path, and the heat emitter emits gaseous high-temperature luminous products of combustion that flow through the windows of the body ca, this indicates that the emitter is predominantly not thermal (wavelength of the infrared range greater than 0.8 microns), but light (wavelength less than 0.75 microns) and, therefore, only heated window edges can emit in the infrared range case, while the heating of these edges occurs some time after the start of the burning of the tracer under the condition of a sufficiently high power tracer, providing this heating in conditions of high-speed blowing in flight;

- the emitter body has a diameter smaller than the caliber of the rocket and the diameter of the lens reflector, and, accordingly, infrared radiation from the edges of the windows is shielded in the directions "forward" and "back" in very significant solid angles;

- the burning time of commercially available tracers, as a rule, is about 30 seconds, and since the tracer turns on simultaneously with the engine starting, its operation time may not be enough for the entire flight path of the ITC.

Known anti-aircraft target missile adopted for the prototype (see patent RU No. 2222767, IPC F42B 8/12, F42B 15/10, publ. 01/27/2004), consisting of a propulsion system with a stabilizer, a radio-transparent head compartment with a cowl and a corner reflector of microwave energy and tracers, in the head compartment in front of the corner reflector of microwave energy, a cartridge block of heat-resistant composite material in the form of thick-walled disks is installed and fixed in the inner cavity of which tracers are placed, while in the body of the head compartment coaxially to the tracers are made portable gas-water holes diametrically located relative to each other, the axes of which are perpendicular to the longitudinal axis of the target missile, the working end surfaces of the tracers being located in the gas-water holes of the head compartment housing, while a direct current source with an electronic delay unit for sequentially activating tracers is installed in the fairing inner cavity.

The disadvantages of the prototype are that:

- due to the eccentricity of the center of mass of the IVC arising from sequential single burning of tracers radially located in the head compartment, it will be diverted from the calculated trajectory in both horizontal and vertical planes, which requires increased safety measures and leads to the need to expand the danger zone , which cannot be provided at a number of military air defense and general-use training grounds, and, accordingly, to the limitation of the conditions for the use of the information and information center;

- tracers provide only illumination of the ITC flight path in the optical wavelength range and do not create a sufficient level of infrared radiation for capture by anti-aircraft missiles with thermal homing heads.

It should also be noted that in the aforementioned inventions, the scattering pattern of the combined corner radar reflectors in the plane perpendicular to the longitudinal axis of the IVC has structurally deep dips (the angular width of the indicatrix at half power is less than 45 ° in each quarter of the cylinder), which is not always enough for radio visibility from all directions.

In addition, it is known that a number of uncontrolled missile-type ITCs flying along ballistic trajectories, including those made on the basis of roll stabilized combat missiles, in addition to aerodynamic stabilization (ensuring the position of the pressure center behind the center of mass) have stabilization by rotation around the longitudinal axis with the aim reduction of the deviation from the calculated trajectory in both horizontal and vertical planes, due to the eccentricities of the thrust, center of mass and shape asymmetry.

Rotation is imparted using various design solutions, for example, by sliding a pin fixed on the side of the IVC, along the spiral groove of the launch tube, the tangential (transverse) orientation of the jet engine nozzles, the complex (propeller) shape of the stabilizers, etc. As a rule, the implementation of such structures is technologically sophisticated, and therefore expensive.

The proposed invention solves the problem: expanding the technical capabilities of the simulator of air targets, increasing its versatility and safety, reducing cost.

The technical result obtained by carrying out the invention consists in developing a design for an inexpensive uncontrolled simulator of air targets that has stable flight paths, has an optimal design for the location and layout of tracers, and a sequence diagram of the work of groups of tracers, starting from the start, can be fired by anti-aircraft missiles with thermal or photo-contrast homing heads "catch up", then, at a safe distance from the launcher - "towards".

The specified technical result is achieved in that in an airborne simulator containing a rocket engine with stabilizers and a head with tracers placed in it, a current source, an electronic delay unit for activating tracers, the new one is that the simulator is equipped with a tail emulator rotation tail around the longitudinal axis, made in the form of flat feathers mounted radially on the engine behind the stabilizers at an angle to the longitudinal axis, the simulator is also equipped with additional tracers (tracers back groups) mounted on the engine and oriented by the working ends backwards, with the possibility of turning them on from the launcher at the start of the ICC, and tracers located in the head part (front group tracers), oriented by the working ends forward with the possibility of turning them on through the delay unit from the on-board source current, in addition, the tracers of each group are located symmetrically relative to the longitudinal axis of the IVC.

The simulator can be equipped with false thermal and / or radar targets mounted on the simulator with the possibility of their shooting on the flight path, a parachute system with the possibility of its inclusion on the flight path, a receiving device associated with the executive (s) device (you).

Providing the device with the tail unit of rotation of the simulator around the longitudinal axis, made in the form of flat feathers mounted radially on the engine behind the stabilizers at an angle to the longitudinal axis, it allows simple and economical rotation of the ITC around the longitudinal axis, which increases the stability of the ITC flight paths and, accordingly, the efficiency and safety of firing. In addition, when the combination of corner reflectors in the IVC is rotated around the axis of symmetry - the longitudinal axis of the target, dips disappear in the scatter diagram due to the formation of the resulting diagram corresponding to the average effective dispersion area, which improves the reflective characteristics of the IVC in the radar range.

Supplying the device with additional tracers (tracers of the rear group), mounted on the engine and oriented by the working ends to the rear, with the possibility of turning them on from the launcher at the start of the ICC, as well as the orientation of tracers located in the head part (tracers of the front group) of the working ends forward, with the possibility switching them on through the delay unit from the on-board current source optimizes the cyclogram and the indicatrix of the radiation of the information and information center, the characteristics of the light and heat fields, the photo-contrast image of the target I wish to set up to carry out the firing of the target from any direction, to reduce the weight, dimensions and, consequently, the value of the target simulation equipment.

The location of the tracers of each group symmetrically with respect to the longitudinal axis avoids the occurrence of eccentricity of the center of mass of the target during their combustion, the removal of the information and information center from the calculated trajectory, and, accordingly, increases the safety of the target.

Equipping the device with false thermal and / or radar targets mounted on the simulator with the possibility of their shooting on the flight path expands the technical capabilities for simulating the characteristics of modern airborne satellites.

Providing the ITC with a parachute system, with the possibility of its inclusion on the flight path, allows you to simulate the characteristics of an attacking combat order helicopter that performs ascent and descent in a short time (“jump”).

Providing the ITC with a receiving device connected with the executive device (s) allows you to shoot interference, open the parachute system, and, according to the operator’s commands, at the moment you need according to the conditions of the exercises.

The combination of structural elements, their relative position, the form of the elements and the relationship between them allow us to provide imitation with a high degree of correspondence of the trajectory, radiative, reflective and noise-stopping characteristics of various IOS.

Technical solutions with features distinguishing the claimed solution from the prototype are not known and do not follow explicitly from the prior art. This suggests that the proposed solution is new and has an inventive step.

The essence of the invention is illustrated in the drawing, which shows a General view of a variant of the proposed ITC without radar reflectors outside the container.

The air target simulator comprises a rocket engine 1 with stabilizers 2, a head part 3 with a current source 4 located therein, tracers 5 of the front group, and an electronic delay unit 6 for activating the tracers of the front group. The tracers 5 are oriented forward by the working ends, installed with the possibility of switching on via the electronic delay unit 6 from the on-board current source 4. The simulator is equipped with a tail feather of the simulator rotation around the longitudinal axis, made in the form of flat feathers 7 mounted radially on the motor 1 behind the stabilizers 2 at an angle to longitudinal axis. On engine 1, additional tracers 8 (rear group) are fixed, oriented backward with the working ends, with the possibility of turning them on from the launcher at the start of the ITC. The tracers of each group are located symmetrically relative to the longitudinal axis of the IVC.

The location of the starting positions of the anti-aircraft systems and the ICC launcher is determined by the combat training or research task.

The ITC flight path is set as directed by the firing director by setting elevation angles and course.

As soon as all units are ready, the firing director sets a fire mission and gives a command to launch the ITC.

In accordance with the cyclogram, the IVC launch equipment supplies electric pulses to electric igniters of the onboard current source 4, tracers 8 of the rear group and rocket engine 1. The target leaves the container and, rotating around the longitudinal axis due to the tail unit, flies along the ballistic trajectory provided by the presence of stabilizers 2, with burning tracers 8, providing visual observation of it, as well as a given level of infrared radiation in the rear hemisphere. In certain sections of a given trajectory, the IVC is included in the operating zone of a given anti-aircraft complex with the necessary trajectory and radiative parameters. After a sufficient time has elapsed to achieve safe removal of the target from the launcher, the electronic delay unit 6 ignites the tracers 5 from the on-board current source 4, and the target can be fired by anti-aircraft missiles with “toward” thermal homing heads.

When equipping the ITC with a receiving device and actuating devices, the operator may send a command to shoot the jammers, open the parachute system, etc.

Conducted theoretical studies and launches of experimental samples of the Information and Information Center showed the correctness and effectiveness of the proposed technical solutions. The Ministry of Defense of the Russian Federation assigned the product index 9F881 to this product; prototypes are being manufactured for interdepartmental testing in order to accept the target for supply.

The implementation of the invention is very inexpensive, since the manufacture is carried out by finalizing decommissioned and subject to disposal of anti-aircraft missiles having zero residual value.

Claims (4)

1. The simulator of air targets, comprising a rocket engine with stabilizers and a head part with tracers placed in it, a current source, an electronic delay unit for activating tracers, characterized in that it is equipped with a tail unit of rotation of the simulator around the longitudinal axis, made in the form of flat feathers fixed radially on the engine behind the stabilizers at an angle to the longitudinal axis, the air targets simulator is also equipped with additional tracers of the rear group, mounted on the engine and oriented backwards, with the possibility of turning them on from the launcher at the start of the simulator of air targets, and the front group tracers located in the head are oriented by the working ends forward with the possibility of turning them on through the delay unit from the on-board current source, in addition, the tracers of each group are located symmetrically about the longitudinal axis of the simulator of air targets. 2. The simulator according to claim 1, characterized in that it is equipped with false thermal and / or radar targets mounted on the simulator with the possibility of their shooting on the flight path. 3. The simulator according to claims 1 and 2, characterized in that it is equipped with a parachute system with the possibility of its inclusion on the flight path. 4. The simulator according to claims 1 to 3, characterized in that it is equipped with a receiving device associated with the executive (s) device (you).