RU2468326C2 - Laser fire simulator - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: simulator has case 1 accommodating radiating channels 2, 3 with matched optical axes. Channel 2 has laser 4 with wavelength in IR band and optical generator system 5 to simulate a shot. Channel 3 comprises laser 6 with wavelength in visible band and optical generator system 7. Simulator device 10 is attached to gun 11. Gunner aims gun 11 to screen 13 to depress knob 8 for aligning simulator radiation axis with sight optical axis. Note here that laser starter 9 starts laser 6 to send visible radiation, continuous or blinking at frequency of 2.5-12 Hz. Gunner uses device 12 to align fire simulator with sight axis to turn simulator relative to gun 11 so that visible laser spot is aligned with sight mark. Trigger actuated, device 9 send laser visible and IR pulses to target.

EFFECT: higher efficiency, expanded performances.

3 cl, 1 dwg

Description

The invention relates to laser training aids and can be used to simulate shooting from small arms at tactical exercises for targets equipped with photoelectronic imitators of defeat, as well as for developing aiming skills both on photoelectronic and conventional targets.

For laser firing simulators, when they are installed on a weapon, requirements are made to ensure the alignment of the axes of radiation and the sight of the weapon, i.e. Laser radiation must fall at the aiming point.

Known laser firing simulators, which provide mechanisms to rotate the axis of the radiation of the firing simulator to align it with the axis of the sight of a simulated weapon, for example, a firing simulator used in the US Army, described in the "prior art" section of the description of the invention to RF patent No. 2123163, date Priority 04/28/1995, IPC F41A 33/02. The simulator contains a radiating channel placed in the housing, simulating a shot, containing a laser with a radiation wavelength in the infrared region of the spectrum and a laser trigger for simulating a shot. To adjust the simulator, a special device is used that contains a photoelectron target of 144 detectors and 35 circuits made on printed circuit boards, placed at a distance of 25 m from the firing simulator, and an electromechanical display. The target is used to determine the point of impact of the laser beam relative reticle in a simulation shot.

The indicated device counts the number of erroneous “clicks” corresponding to the deviation of the beam from the target in azimuth and elevation angle. Then, the number of clicks is displayed using four sets of display indicators. After that, the shooter should turn the usual adjustments of his laser transmitter in the right direction by the appropriate number of clicks. Then the shooter must re-aim the weapon, fire a shot and perform additional appropriate adjustment. This process continues until the shooter reaches a zero correction display. Due to common sighting errors that occur every time you have to re-align the sight with the reticle, this process is tedious and time consuming.

The disadvantages of this solution are the length of the alignment process and the need to use a special device with a photoelectron target.

Known laser firing simulator for handguns designed for tactical exercises. The simulator is attached to the rifle box, for example, M16. The simulator contains a laser emitter located in the housing simulating a shot, an optical system, a shot sensor, rotary deflecting optical wedges and two shafts that rotate these wedges. Using wedges, the laser beam is deflected in azimuth and elevation. Coordination of the radiation axis of the shooting simulator with the axis of the sight of the simulated weapon is carried out using a special adjustment head. Weapons with a simulator are installed in a clip in front of a special device with photodetectors to determine the point of impact of the laser beam and control the alignment head.

An adjustment head is connected to the simulator to rotate the wedges and the beam is deflected by wedges until its axis coincides with the axis of the rifle’s sight (WO 9530124 A1, priority date 04/28/1995, IPC F41A 33/02; US 5476385 (A), priority date 04/03/1995, IPC F41A 33/02).

The disadvantage of such a simulator is the need to have an adjustment head for rotating the wedges and a special device with photodetectors to determine the point of impact of the laser beam and control the adjustment head.

The closest in technical essence to the claimed one - the prototype - is a laser firing simulator IS1 kit 9F838, manufactured by FSUE "PO" NPZ ", Novosibirsk (Kit 9F838. Operation manual AL2.890.019 RE, 2008, pp. 11-14 27-29, 66-67). A laser firing simulator contains a radiating channel simulating a shot containing an optically coupled laser with a radiation wavelength in the infrared region of the spectrum and forming an optical system, as well as a laser trigger for a firing shot. The radiating channel is placed in the housing, which is equipped with a device for mounting it on a simulated weapon or weapon model and a mechanism for reconciling a firing simulator with the axis of the sight of a simulated weapon or weapon model.

In addition, the prototype has a second emitting channel with a wavelength of radiation in the infrared region of the spectrum, simulating a shot, namely shelling a target.

The prototype has the following disadvantages.

To coordinate the infrared axis of the shooting simulator and the axis of the sight of the simulated weapon or weapon model, a special reconciliation device (one device for several simulators) is required, which allows to determine the point of impact of the laser beam. The presence of an additional device complicates the operation of simulators.

Before matching the firing simulator with a gun sight, the shooter must first fix the alignment device on the firing simulator and move the alignment device grid to coordinate the alignment device axis with the radiation axis of the firing simulator. Then the shooter points the weapon’s sight at a remote point and, observing through the reconciliation device, rotates the screws of the reconciling mechanism of the shooting simulator by pointing the grid of the reconciliation device to the same remote point.

When reconciling a simulator with a weapon, the operator cannot simultaneously observe the aiming point of the weapon and the pointing point of the reconciliation device. Therefore, when coordinating, a rigid fastening of the weapon with a simulator in the machine is required so that the aiming of the sight on the target does not stray. Sequential observation in two devices increases the coordination time, which increases the preparation time of the unit for exercises.

In addition, the simulator does not simulate the place of hit during a miss and the flash of a shot in electronic shooting mode (without the use of blank cartridges).

In some cases, in combat shooting, the shooter sees the place where the bullet hit (fountains of dust, chips, sparks) and has the ability to adjust his shooting. In the prototype with radiation in the infrared region of the spectrum, there is no simulation of this effect: the shooter sees the reaction of the photoelectron target when the laser beam hits, but does not see the place of the hit when it misses.

In addition, the fired shooter in a real battle observes a flash of an enemy shot, and in the prototype simulator this effect of a real IR-ray firing is not imitated.

When training firing skills of a fighter, it is necessary to train the ability to properly aim at a target (target). In the prototype, this problem is partially solved, and only when firing at a special photoelectron target that detects infrared radiation: the fighter sees the result only when it hits the target and does not see where it was missed.

The objective of the invention is to simplify the alignment of the radiation axis of the firing simulator and the axis of the sight of the simulated weapon or weapon layout, approximating the training conditions to the real one by simulating a shot flash and visualizing the point of impact, as well as expanding the simulator's functionality by visualizing the point of contact with a regular target that is not a photoelectron target .

The problem is solved in that in the laser firing simulator, as in the prototype containing the emitting channel, simulating a shot containing optically coupled to the first laser with a radiation wavelength in the infrared region of the spectrum and the first forming optical system, as well as a laser launch device, the emitting channel is housed in a housing equipped with a device for mounting it on a simulated weapon or weapon model and a mechanism for reconciling a firing simulator with the axis of the sight of a simulated weapon or weapon model, unlike the prototype the following has been done: it is equipped with a second emitting channel located in the housing, which contains an optically coupled second laser and a second forming optical system, and is connected to the laser launch device by a device for switching on the mode of matching the radiation axis of the firing simulator with the optical axis of the sight; the optical axis of both radiating channels are consistent with each other; the second laser has a wavelength of radiation in the visible region of the spectrum; the laser trigger device is configured to trigger the lasers as follows: when simulating a shot - launching a second laser in a pulsed mode of operation, and when the matching mode is turned on by the above-mentioned device - launching a second laser in a continuous or flashing mode.

A sufficiently accurate coordination of the axis of radiation of the firing simulator and the axis of the sight of the simulated weapon or model of the weapon is achieved when the beam divergence of the second emitting channel does not exceed 0.5 mrad. With a narrow beam, the illumination of the laser spot increases, it can be seen at a greater firing range, therefore, a simulation of a flash of a shot and visualization of the point of impact is carried out at a greater firing range.

In general, a semiconductor, solid state, or gas laser can be used. A semiconductor laser is preferable because of its weight and size characteristics and manufacturability.

The figure shows an example of a specific implementation of a laser shooting simulator mounted on a simulated weapon.

The laser firing simulator comprises a housing 1 in which emitting channels 2, 3 are placed, the optical axes of which are technologically matched. The emitting channel 2 contains an optically coupled laser 4 with a radiation wavelength in the infrared region of the spectrum and forming the optical system 5, its radiation simulates a shot. The emitting channel 3 contains an optically coupled laser 6 with a radiation wavelength in the visible region of the spectrum and forming an optical system 7. The simulator also includes a device for switching on the mode of matching the radiation axis of the firing simulator with the optical axis of the sight, made in the form of a button 8. Lasers 4 and 6 are connected with a laser trigger device 9. The housing 1 is equipped with a device 10 for mounting on weapons 11 and a mechanism 12 for reconciling the firing simulator with the axis of the sight (not shown) of the weapon 10. The laser firing simulator is verified on screen 13.

An imitation shot can be fired when the lasers 4 and 6 are launched from an empty shot or when the electron trigger is started by pressing the trigger of the weapon 11. The laser launch device 9 may contain, for example, a piezoceramic element and / or an electronic start button, which start the simulation shot preparation cycle, and a control device (microprocessor) issuing a command to start lasers 4 and 6, depending on the state of the participant’s own simulator of defeat and other conditions.

The device operates as follows. The firing simulator is fixed on the weapon 11 and before the start of the simulation firing, the firing simulator is reconciled with the sight of the weapon. The mechanism 12 of reconciliation of the firing simulator with the axis of the sight of a simulated weapon or a mock-up of a weapon can be made in the form of a bracket mounted on a weapon and connected to the simulator body via spring-loaded handwheels, as, for example, in prototype 9F838.

The coordination of the radiation axis of the emitting channel 2, simulating firing, and the sight of the weapon 11 is carried out using a screen 13 mounted at a distance of, as a rule, 20-30 m. A normal target or wall can serve as a screen 13.

The shooter, looking at the sight, directs the weapon to the screen 13 and with the button 8 turns on the coordination mode. In this case, the laser start device 9 starts the laser 6 and the emitting channel 3 sends visible radiation to the screen 13, for example, a red beam. Laser 6 can operate in a continuous glow mode or in a blinking mode with a frequency of 2.5-12 Hz. The frequency range is determined by the frequency of flickers perceived by the eye. In blinking mode, better eye detection is achieved. Since the visibility of the blinking spot is higher, this allows you to see it at a greater range.

If the aiming mark of the sight does not coincide with the laser radiation spot of the shooter using the handwheels of the mechanism 12 for reconciling the firing simulator with the axis of the sight of the weapon, the simulator is deployed relative to the weapon, the laser spot and the mark of the sight are aligned and the laser is turned off. 6. The firing simulator is ready for operation. The presence of a visible channel makes it possible to simplify the coordination process; no special reconciliation device is required. Coordination can be carried out without hard mounting weapons 11 on the machine, because the aiming point is the visible laser spot.

When simulating shooting, the shooter takes aim at the target, equipped with a photoelectronic simulator of defeat, and presses the trigger of the weapon 11. In this case, the launch device 9 launches lasers 4 and 6, and pulses of infrared radiation and visible radiation are sent to the target. With proper aiming, the IR beam is detected by photodetectors on the target and the hit on the target is simulated.

When the divergence of the beam of the radiating channel 3 does not exceed 0.5 mrad, the red spot is clearly visible on the screen 13 at the matching ranges.

The spot size provides sufficient accuracy for matching the firing simulator with the sight.

The shooter who receives the radiation sees a red flash of a "firing" weapon. Thus, an imitation of the real effect of shooting is achieved, and the visibility of training is increased.

The shooter, who shoots, sees the point of impact of the red beam and can evaluate the correct aiming and adjust the shooting. This also imitates the real effect of shooting.

When training in shooting skills, the simulator can be used with a conventional, non-photoelectron target, thereby expanding its functionality. The shooter sees a red dot on any target when hit and miss.

Thus, in comparison with the prototype, the claimed technical solution makes it possible to simplify the coordination of the radiation axis of the firing simulator and the axis of the sight of a simulated weapon or mock-up of weapons, to bring training conditions closer to the real ones by simulating a flash of a shot and visualizing the point of impact, as well as expand the functionality of the firing simulator by visualizing hit points when using conventional targets other than photoelectron targets.

Claims (3)

1. Laser firing simulator containing a radiating channel, simulating a shot containing optically coupled to a first laser with a radiation wavelength in the infrared region of the spectrum and a first forming optical system, as well as a laser trigger, the radiating channel being housed in a housing equipped with a fixture on a simulated weapon or model of a weapon and a mechanism for reconciling a shooting simulator with the axis of the sight of a simulated weapon or model of a weapon, characterized in that it contains a second emitting channel comprising an optically coupled second laser and a second forming optical system, as well as a matching mode switching device associated with the laser trigger, the optical axes of the emitting channels being aligned, the second laser having a radiation wavelength in the visible region of the spectrum, and the laser trigger the possibility, when simulating a shot, of starting together with the first laser of the second laser in a pulsed mode of operation, and when the matching-launch mode of the second laser is switched on in continuous or ayuschem operation. 2. The laser firing simulator according to claim 1, characterized in that the divergence of the laser beam of the second emitting channel does not exceed 0.5 mrad. 3. The laser firing simulator according to claim 1, characterized in that a semiconductor laser is used as the second laser.